Biotechnological synthesis process of omega-functionalized carbon acids and carbon acid esters from simple carbon sources

ABSTRACT

The subject of the invention is a biotechnological process for the production of ω-functionalized carboxylic acids and of ω-functionalized carboxylate esters from simple carbon sources.

FIELD OF INVENTION

The subject of the invention is a biotechnological process for the production of ω-functionalized carboxylic acids and ω-functionalized carboxylate esters from simple carbon sources.

PRIOR ART

The biotechnological production of ω-functionalized carboxylic acids and the corresponding esters has previously been described exclusively in the form of biotransformations, wherein the corresponding carboxylic acid as substrate is contacted with an appropriate biological cell, which catalyses the necessary reactions enzymatically.

Such a process and cells which are suitable for the production of the ω-aminocarboxylic acids and esters thereof are for example described in WO2009077461.

EP2322598 also describes the production of ω-hydroxycarboxylic acids and esters thereof in specially equipped Candida tropicalis cells from fatty acids as the substrate used. A very similar procedure is described in WO2011008232, wherein Candida cells, wherein the β-oxidation is blocked, form corresponding ω-functionalized carboxylic acids and diacids starting from fatty acids by enzymatic oxidation.

The fatty acids and derivatives thereof required as substrates are mainly obtained nowadays exclusively from plant and animal oils or fats. This has a large number of disadvantages:

In particular, as a consequence of the BSE crisis, animal fats as raw materials still meet little client acceptance. Plant oils which contain short- and middle-length fatty acids are either difficult to obtain or are produced in tropical regions. Here the sustainability of production is in many cases called into question, since in some cases rainforest is cleared in order to provide the cultivation areas.

In addition, particular plant and animal oil or fat raw materials have specific, but defined fatty acid profiles. Hence coupled production takes place here, which can be price-determining for a certain fatty acid species. Last but not least, many of the plant oils are simultaneously also foodstuffs, so that under certain conditions a competition can arise between use as a substance and use as a foodstuff.

The purpose of the invention was to provide a biotechnological process for the production of ω-functionalized carboxylic acids and ω-functionalized carboxylate esters which is not reliant on fatty acids as educts.

DESCRIPTION OF THE INVENTION

Surprisingly, it has been found that the cells described below containing genetic modifications are capable of solving the problem posed for the invention.

Hence a subject of the present invention are microorganisms which synthesize increased amounts of carboxylic acids or carboxylate esters and on the basis of further genetic features provide these with an ω-functionality.

A further subject of the invention is the use of the aforesaid microorganisms for the production of ω-functionalized carboxylic acids and ω-functionalized carboxylate esters and a process for the production of ω-functionalized carboxylic acids and ω-functionalized carboxylate esters with use of the microorganisms.

An advantage of the present invention is that the product inhibition in the production process can be markedly reduced.

A further advantage of the present invention is that the process enables the production of ω-functionalized carboxylic acids and ω-functionalized carboxylate esters from unrelated carbon sources with high space-time yield, high carbon yield and high concentration in the culture supernatant. As a result of the latter in particular, an efficient workup is facilitated.

The invention comprises methods for the generation of recombinant microbial cells which are capable of producing ω-functionalized carboxylic acids and ω-functionalized carboxylate esters from unrelated carbon sources.

The present invention thus comprises a microorganism, which has a first genetic modification, so that compared to its wild type it is capable of forming more carboxylic acid or carboxylate ester from at least one simple carbon source, characterized in that the microorganism has a second genetic modification, which comprises that the microorganism has, in comparison to its wild type, increased activity

of at least one enzyme E₁ which catalyses the conversion of carboxylic acids or carboxylate esters to the corresponding ω-hydroxycarboxylic acids or ω-hydroxycarboxylate esters.

In connection with the present invention, the term “a first genetic modification” is understood to mean at least one genetic engineering alteration of the microorganism, whereby the expression of one or more genes has been modified, i.e. increased or reduced, compared to the wild type strain.

In connection with the present invention, the term “simple carbon source” is understood to mean carbon sources wherein in the carbon skeleton at least one C—C bond has been broken and/or at least one carbon atom of the simple carbon source must form at least one new bond with at least one carbon atom of another molecule, in order to arrive at the carbon skeleton of the “more carboxylic acid or carboxylate ester”.

All stated percentages (%) are, unless otherwise stated, mass percent.

As the carbon source, carbohydrates such as for example glucose, saccharose, arabinose, xylose, lactose, fructose, maltose, molasses, starch, cellulose and hemicellulose, but also glycerin or very simple organic molecules such as CO₂, CO or synthesis gas, can be used.

Preferred carboxylic acids or carboxylate esters of the present invention are those which have more than one, in particular 3 to 36, preferably 6 to 24, in particular 10 to 14 carbon atoms in the carboxylic acid chain. This can be linear, branched, saturated or unsaturated and optionally substituted with other groups.

The carboxylate esters are preferably those wherein the alcohol component is derived from methanol, ethanol or other primary alcohols with 3-18 carbon atoms, in particular methanol and ethanol.

Particularly preferably, the carboxylic acids are fatty acids selected from the group formic acid, acetic acid, propionic acid, butyric acid, valeric acid, caproic acid, oenanthic acid, caprylic acid, pelargonic acid, capric acid, lauric acid, myristic acid, pentadecanoic acid, palmitic acid, margaric acid, stearic acid, nonadecanoic acid, arachic acid, behenic acid, lignoceric acid, cerotic acid, Montan acid, melissic acid, undecylenic acid, myristoleic acid, petroselic acid, oleic acid, elaidic acid, vaccenic acid, gadoleic acid, icosenic acid, cetoleic acid, erucic acid, nervoic acid, linolic acid, α-linolenic acid, γ-linolenic acid, calendula acid, punicic acid, α-elaeostearic acid, β-elaeostearic acid, arachidonic acid, timnodonic acid, clupanodonic acid, cervonic acid, vernolic acid, ricinoleic acid

and esters thereof, wherein the fatty acid esters are preferably those wherein the alcohol component is derived from methanol, ethanol or other primary alcohols with 3-18 carbon atoms, in particular methanol and ethanol.

It is preferable according to the invention that microorganisms are used on the basis of good genetic accessibility; selected from the group of the bacteria, particularly from the group containing, preferably consisting of, Abiotrophia, Acalyochloris, Accumulibacter, Acetivibrio, Acetobacter, Acetohalobium, Acetonema, Achromobacter, Acidaminococcus, Acidimicrobium, Acidiphilium, Acidithiobacillus, Acidobacterium, Acidothermus, Acidovorax, Acinetobacter, Actinobacillus, Actinomyces, Actinosynnema, Aerococcus, Aeromicrobium, Aeromonas, Afipia, Aggregatibacter, Agrobacterium, Ahrensia, Akkermansia, Alcanivorax, Alicycliphilus, Alicyclobacillus, Aliivibrio, Alkalilimnicola, Alkaliphilus, Allochromatium, Alteromonadales, Alteromonas, Aminobacterium, Aminomonas, Ammonifex, Amycolatopsis, Amycolicicoccus, Anabaena, Anaerobaculum, Anaerococcus, Anaerofustis, Anaerolinea, Anaeromyxobacter, Anaerostipes, Anaerotruncus, Anaplasma, Anoxybacillus, Aquifex, Arcanobacterium, Arcobacter, Aromatoleum, Arthrobacter, Arthrospira, Asticcacaulis, Atopobium, Aurantimonas, Azoarcus, Azorhizobium, Azospirillum, Azotobacter, Bacillus, Bartonella, Basfia, Baumannia, Bdellovibrio, Beggiatoa, Beijerinckia, Bermanella, Beutenbergia, Bifidobacterium, Bilophila, Blastopirellula, Blautia, Blochmannia, Bordetella, Borrelia, Brachybacterium, Brachyspira, Bradyrhizobium, Brevibacillus, Brevibacterium, Brevundimonas, Brucella, Buchnera, Bulleidia, Burkholderia, Butyrivibrio, Caldalkalibacillus, Caldanaerobacter, Caldicellulosiruptor, Calditerrivibrio, Caminibacter, Campylobacter, Carboxydibrachium, Carboxydothermus, Cardiobacterium, Carnobacterium, Carsonella, Catenibacterium, Catenulispora, Catonella, Caulobacter, Cellulomonas, Cellvibrio, Centipeda, Chelativorans, Chloroflexus, Chromobacterium, Chromohalobacter, Chthoniobacter, Citreicella, Citrobacter, Citromicrobium, Clavibacter, Cloacamonas, Clostridium, Collinsella, Colwellia, Comamonas, Conexibacter, Congregibacter, Coprobacillus, Coprococcus, Coprothermobacter, Coraliomargarita, Coriobacterium, corrodens, Corynebacterium, Coxiella, Crocosphaera, Cronobacter, Ctyptobacterium, Cupriavidus, Cyanobium, Cyanothece, Cylindrospermopsis, Dechloromonas, Deferribacter, Dehalococcoides, Dehalogenimonas, Deinococcus, Delftia, Denitrovibrio, Dermacoccus, Desmospora, Desulfarculus, Desulphateibacillum, Desulfitobacterium, Desulfobacca, Desulfobacterium, Desulfobulbus, Desulfococcus, Desulfohalobium, Desulfomicrobium, Desulfonatronospira, Desulforudis, Desulfotalea, Desulfotomaculum, Desulfovibrio, Desulfurispirillum, Desulfurobacterium, Desulfuromonas, Dethiobacter, Dethiosulfovibrio, Dialister, Dichelobacter, Dickeya, Dictyoglomus, Dietzia, Dinoroseobacter, Dorea, Edwardsiella, Ehrlichia, Eikenella, Elusimicrobium, Endoriftia, Enhydrobacter, Enterobacter, Enterococcus, Epulopiscium, Erwinia, Erysipelothrix, Etythrobacter, Escherichia, Ethanoligenens, Eubacterium, Eubacterium, Exiguobacterium, Faecalibacterium, Ferrimonas, Fervidobacterium, Fibrobacter, Finegoldia, Flexistipes, Francisella, Frankia, Fructobacillus, Fulvimarina, Fusobacterium, Gallibacterium, Gallionella, Gardnerella, Gemella, Gemmata, Gemmatimonas, Geobacillus, Geobacter, Geodermatophilus, Glaciecola, Gloeobacter, Glossina, Gluconacetobacter, Gordonia, Granulibacter, Granulicatella, Grimontia, Haemophilus, Hahella, Halanaerobiumns, Haliangium, Halomonas, Halorhodospira, Halothermothrix, Halothiobacillus, Hamiltonella, Helicobacter, Heliobacterium, Herbaspirillum, Herminiimonas, Herpetosiphon, Hippea, Hirschia, Histophilus, Hodgkinia, Hoeflea, Holdemania, Hydrogenivirga, Hydrogenobaculum, Hylemonella, Hyphomicrobium, Hyphomonas, Idiomarina, Ilyobacter, Intrasporangium, Isoptericola, Isosphaera, Janibacter, Janthinobacterium, Jonesia, Jonquetella, Kangiella, Ketogulonicigenium, Kineococcus, Kingella, Klebsiella, Kocuria, Koribacter, Kosmotoga, Kribbella, Ktedonobacter, Kytococcus, Labrenzia, Lactobacillus, Lactococcus, Laribacter, Lautropia, Lawsonia, Legionella, Leifsonia, Lentisphaera, Leptolyngbya, Leptospira, Leptothrix, Leptotrichia, Leuconostoc, Liberibacter, Limnobacter, Listeria, Loktanella, Lutiella, Lyngbya, Lysinibacillus, Macrococcus, Magnetococcus, Magnetospirillum, Mahella, Mannheimia, Maricaulis, Marinithermus, Marinobacter, Marinomonas, Mariprofundus, Maritimibacter, Marvinbryantia, Megasphaera, Meiothermus, Melissococcus, Mesorhizobium, Methylacidiphilum, Methylibium, Methylobacillus, Methylobacter, Methylobacterium, Methylococcus, Methylocystis, Methylomicrobium, Methylophaga, Methylophilales, Methylosinus, Methyloversatilis, Methylovorus, Microbacterium, Micrococcus, Microcoleus, Microcystis, Microlunatus, Micromonospora, Mitsuokella, Mobiluncus, MooreIla, Moraxella, Moritella, Mycobacterium, Myxococcus, Nakamurella, Natranaerobius, Neisseria, Neorickettsia, Neptuniibacter, Nitratifractor, Nitratiruptor, Nitrobacter, Nitrococcus, Nitrosomonas, Nitrosospira, Nitrospira, Nocardia, Nocardioides, Nocardiopsis, Nodularia, Nostoc, Novosphingobium, Oceanibulbus, Oceanicaulis, Oceanicola, Oceanithermus, Oceanobacillus, Ochrobactrum, Octadecabacter, Odyssella, Oligotropha, Olsenella, Opitutus, Oribacterium, Orientia, Ornithinibacillus, Oscillatoria, Oscillochloris, Oxalobacter, Paenibacillus, Pantoea, Paracoccus, Parascardovia, Parasutterella, Parvibaculum, Parvimonas, Parvularcula, Pasteurella, Pasteuria, Pectobacterium, Pediococcus, Pedosphaera, Pelagibaca, Pelagibacter, Pelobacter, Pelotomaculum, Peptoniphilus, Peptostreptococcus, Persephonella, Petrotoga, Phaeobacter, Phascolarctobacterium, Phenylobacterium, Photobacterium, Pirellula, Planctomyces, Planococcus, Plesiocystis, Polaromonas, Polaromonas, Polymorphum, Polynucleobacter, Poribacteria, Prochlorococcus, Propionibacterium, Proteus, Providencia, Pseudoalteromonas, Pseudo flavonifractor, Pseudomonas, Pseudonocardia, Pseudoramibacter, Pseudovibrio, Pseudoxanthomonas, Psychrobacter, Psychromonas, Puniceispirillum, Pusiffimonas, Pyramidobacter, Rahnella, Ralstonia, Raphidiopsis, Regiella, Reinekea, Renibacterium, Rhizobium, Rhodobacter, Rhodococcus, Rhodoferax, Rhodomicrobium, Rhodopirellula, Rhodopseudomonas, Rhodospirillum, Rickettsia, Rickettsiella, Riesia, Roseburia, Roseibium, Roseiflexus, Roseobacter, Roseomonas, Roseovarius, Rothia, Rubrivivax, Rubrobacter, Ruegeria, Ruminococcus, Ruthia, Saccharomonospora, Saccharophagus, Saccharopolyspora, Sagittula, Salinispora, Salmonella, Sanguibacte, Scardovia, Sebaldella, Segniliparus, Selenomonas, Serratia, Shewanella, Shigella, Shuttleworthia, Sideroxydans, Silicibacter, Simonsiella, Sinorhizobium, Slackia, Sodalis, Solibacter, Solobacterium, Sorangium, Sphaerobacter, Sphingobium, Sphingomonas, Sphingopyxis, Spirochaeta, Sporosarcina, Stackebrandtia, Staphylococcus, Starkeya, Stenotrophomonas, Stigmatella, Streptobacillus, Streptococcus, Streptomyces, Streptosporangium, Subdoligranulum, subvibrioides, Succinatimonas, Sulfitobacter, Sulfobacillus, Sulfuricurvum, Sulfurihydrogenibium, Sulfurimonas, Sulfurospirillum, Sulfurovum, Sutterella, Symbiobacterium, Synechocystis, Syntrophobacter, Syntrophobotulus, Syntrophomonas, Syntrophothermus, Syntrophus, taiwanensis, Taylorella, Teredinibacter, Terriglobus, Thalassiobium, Thauera, Thermaerobacter, Thermanaerovibrio, Thermincola, Thermoanaerobacter, Thermoanaerobacterium, Thermobaculum, Thermobifida, Thermobispora, Thermocrinis, Thermodesulphateator, Thermodesulfobacterium, Thermodesulfobium, Thermodesulfovibrio, Thermomicrobium, Thermomonospora, Thermosediminibacter, Thermosinus, Thermosipho, Thermosynechococcus, Thermotoga, Thermovibrio, Thermus, Thioalkalimicrobium, Thioalkalivibrio, Thiobacillus, Thiomicrospira, Thiomonas, Tolumonas, Treponema, tribocorum, Trichodesmium, Tropheryma, Truepera, Tsukamurella, Turicibacter, Variovorax, Veillonella, Verminephrobacter, Verrucomicrobium, Verrucosispora, Vesicomyosocius, Vibrio, Vibrionales, Victivallis, Weissella, Wigglesworthia, Wolbachia, Wolinella, Xanthobacter, Xanthomonas, Xenorhabdus, Xylanimonas, Xylella, Yersinia, Zinderia and Zymomonas, in particular E. coli, Pseudomonas sp., Pseudomonas fluorescens, Pseudomonas putida, Pseudomonas stutzeri, Acinetobacter sp., Burkholderia sp., Burkholderia thailandensis, Cyanobakterien, Klebsiella sp., Klebsiella oxytoca, Salmonella sp., Rhizobium sp. and Rhizobium meliloti, Bacillus sp., Bacillus subtilis, Clostridium sp., Corynebacterium sp., Corynebacterium glutamicum, Brevibacterium sp., Chlorella sp. and Nostoc sp., with E. coli being particularly preferable.

In comparison to its wild type, a microorganism according to the invention displays increased activity of at least one enzyme E₁.

The term “increased activity of an enzyme”, as it is used above and in the following explanations in connection with the present invention is preferably to be understood as increased intracellular activity.

The explanations now following concerning the increasing of the enzyme activity in cells apply both for the increasing of the activity of the enzyme E₁ and also for all enzymes mentioned below whose activity can optionally be increased, and also for increased formation of alkL gene product.

Essentially, an increase in the enzymatic activity can be achieved by increasing the copy number of the gene sequence or of the gene sequences which code for the enzyme, using a strong promoter, altering the codon utilization of the gene, increasing the half-life of the mRNA or of the enzyme in various ways, modifying the regulation of the expression of the gene or utilizing a gene or allele which codes for a corresponding enzyme with increased activity and optionally combining these measures. Microorganisms genetically modified according to the invention are for example created by transformation, transduction, conjugation or a combination of these methods with a vector which contains the desired gene, an allele of this gene or parts thereof and contains a promoter enabling the expression of the gene. The heterologous expression is in particular achieved by integration of the gene or the allele into the chromosome of the cell or an extrachromosomally replicating vector.

An overview of the possibilities for increasing the enzyme activity in cells, with pyruvate carboxylase as the example, is given DE-A-100 31 999, which is herewith incorporated as a reference and the disclosure content whereof forms one part of the disclosure of the present invention regarding the possibilities for increasing enzyme activity in cells.

The expression of the enzymes and genes mentioned above and all mentioned below is determinable by means of 1- and 2-dimensional protein gel separation followed by optical identification of the protein concentration in the gel with appropriate evaluation software.

If the increasing of an enzyme activity is based exclusively on increasing the expression of the corresponding gene, then the quantification of the increasing of the enzyme activity can be simply determined by a comparison of the 1- or 2-dimensional protein separations between wild type and genetically modified cell. A common method for the preparation of the protein gels with bacteria and for identification of the proteins is the procedure described by Hermann et al. (Electrophoresis, 22: 1712-23 (2001). The protein concentration can also be analysed by Western blot hybridization with an antibody specific for the protein to be determined (Sambrook et al., Molecular Cloning: a laboratory manual, 2nd Ed. Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y. USA, 1989) followed by optical evaluation with appropriate software for concentration determination (Lohaus and Meyer (1989) Biospektrum, 5: 32-39; Lottspeich (1999), Angewandte Chemie 111: 2630-2647).

This method is also always an option when possible products of the reaction to be catalysed by the enzyme activity to be determined may be rapidly metabolized in the microorganism or else the activity in the wild type is itself too low for it to be possible adequately to determine the enzyme activity to be determined on the basis of the production formation.

With regard to the enzyme E₁, the conversion of lauric acid and/or methyl laurate to ω-hydroxylauric acid and/or methyl ω-hydroxylaurate is understood in particular as a measure of the enzyme activity.

Specified Enzymes E₁

It is preferable according to the invention if in the microorganism the enzyme E₁ is selected from the group:

E_(1a) P450 alkane hydroxylases, which preferentially catalyse the following reactions: reduced haem+alkanoic acid (ester)=oxidized haem+ω-hydroxyalkanoic acid (ester)+H₂O, 2 reduced haem+alkanoic acid (ester)=2 oxidized haem+ω-oxoalkanoic acid (ester)+2H₂O or 3 reduced haem+alkanoic acid (ester)=alkane monooxygenase+3 oxidized haem+ω-carboxyalkanoic acid (ester)+3H₂O and preferably are a component of a reaction system consisting of the two enzyme components “cytochrome P450 alkane hydroxylase and NADPH cytochrome P450 oxidoreductase of EC 1.6.2.4” or a component of a reaction system consisting of the three enzyme components “cytochrome P450 alkane hydroxylase of the CYP_(—)153 type, ferredoxin NAD(P)⁺ reductases of EC 1.18.1.2 or EC 1.18.1.3 and ferredoxin”, and E_(1b) AlkB alkane hydroxylases of EC 1.14.15.3, which preferentially catalyse the following reactions: reduced rubredoxin+alkanoic acid (ester)=oxidized rubredoxin+ω-hydroxyalkanoic acid (ester)+H₂O, 2 reduced rubredoxins+alkanoic acid (ester)=2 oxidized rubredoxins+ω-oxoalkanoic acid (ester)+2H₂O or 3 reduced rubredoxins+alkanoic acid (ester)=alkane monooxygenase+3 oxidized rubredoxins+ω-carboxyalkanoic acid (ester)+3H₂O and preferably are a component of a reaction system consisting of the three enzyme components “AlkB alkane hydroxylase of EC 1.14.15.3, AlkT rubredoxin NAD(P)⁺ reductase of EC 1.18.1.1 or of EC 1.18.1.4 and rubredoxin AlkG”.

The access numbers stated in connection with the present invention correspond to the NCBI ProteinBank database entries with the date 26.07.2011; as a rule, the version number of the entry is identified here by “numerals” such as for example “0.1”.

P450 alkane hydroxylases preferred in this connection are selected from the list

AAO73954.1, AAO73953.1, XP_(—)002546279.1, AAA34353.2, P30607.1, XP_(—)002421627.1, XP_(—)718670.1, CAA39366.1, XP_(—)001527524.1, AAO73955.1, AAO73956.1, XP_(—)002546278.1, EEQ43157.1, XP_(—)718669.1, AAA34354.1, P10615.3, XP_(—)002421628.1, 226487, P16141.3, CAA39367.1, Q9Y757.2, XP_(—)001485567.1, AAO73958.1, XP_(—)001383506.2, XP_(—)460111.2, AAO73959.1, Q12586.1, XP_(—)460112.2, AAO73960.1, Q12589.1, AAO73961.1, XP_(—)460110.2, EEQ43763.1, XP_(—)710174.1, EDK41572.2, XP_(—)001482650.1, CAA75058.1, XP_(—)002548818.1, Q12588.1, XP_(—)002422222.1, XP_(—)001383636.2, XP_(—)001525381.1, XP_(—)002548823.1, P30610.1, AAO73952.1, XP_(—)002548428.1, CAA36197.1, XP_(—)002421126.1, AAA34320.1, P16496.3, P30608.1, P24458.1, XP_(—)717999.1, XP_(—)001383817.1, Q9Y758.1, XP_(—)001482092.1, XP_(—)001383710.2, P30609.1, AAB24479.1, XP_(—)457792.1, XP_(—)001524144.1, XP_(—)457727.2, XP_(—)001525578.1, XP_(—)002616743.1, XP_(—)002614836.1, XP_(—)001525577.1, AAO73957.1, Q12585.1, XP_(—)001386440.2, XP_(—)002616857.1, XP_(—)001483276.1, XP_(—)500402.1, EDK39907.2, XP_(—)500560.1, XP_(—)001211376.1, XP_(—)002560027.1, XP_(—)504857.1, XP_(—)500855.1, XP_(—)504406.1, BAA31433.1, XP_(—)500856.1, XP_(—)501148.1, XP_(—)746567.1, XP_(—)001262425.1, XP_(—)001274843.1, XP_(—)002840588.1, XP_(—)002377641.1, XP_(—)001825995.1, XP_(—)001400739.1, XP_(—)718066.1, CAA35593.1, XP_(—)664735.1, XP_(—)002150795.1, XP_(—)500097.1, XP_(—)002483325.1, XP_(—)504311.1, XP_(—)500273.1, XP_(—)002548817.1, EDP54484.1, XP_(—)755288.1, XP_(—)001260447.1, EFY97851.1, ACD75398.1, ADK36660.1, XP_(—)001213081.1, XP_(—)002377989.1, XP_(—)001826299.1, XP_(—)001554811.1, XP_(—)501667.1, XP_(—)002148942.1, ADK36662.1, XP_(—)002565827.1, P30611.1, XP_(—)001267871.1, XP_(—)002372373.1, EFY84686.1, P43083.1, XP_(—)001263094.1, XP_(—)002148355.1, XP_(—)002568429.1, XP_(—)001817314.1, Q12587.1, XP_(—)001396435.1, XP_(—)001938589.1, XP_(—)001388497.2, XP_(—)663661.1, XP_(—)003295335.1, XP_(—)002152088.1, XP_(—)001212071.1, Q12573.1, XP_(—)002379858.1, XP_(—)001821592.1, XP_(—)002844341.1, XP_(—)001394678.1, ACD75400.1, BAK03594.1, XP_(—)003170343.1, XP_(—)001265480.1, XP_(—)002550661.1, EDP55514.1, XP_(—)001528842.1, XP_(—)749919.1, XP_(—)001593058.1, P30612.1, EGC48494.1, EEH04429.1, XP_(—)001585586.1, XP_(—)003236182.1, XP_(—)001400199.1, EEQ46951.1, XP_(—)721410.1, EGP87864.1, XP_(—)002380808.1, XP_(—)001792771.1, XP_(—)001208515.1, XP_(—)001216161.1, XP_(—)003071804.1, EFW16963.1, XP_(—)002542118.1, XP_(—)001936677.1, EGD95268.1, XP_(—)003015678.1, XP_(—)501748.1, XP_(—)003169562.1, EFY96492.1, XP_(—)682653.1, XP_(—)002421356.1, CAK43439.1, EFY93677.1, XP_(—)747767.1, XP_(—)001244958.1, XP_(—)003019635.1, XP_(—)002847463.1, EGP83273.1, EGR52487.1, XP_(—)002622526.1, XP_(—)002563618.1, CBX99718.1, XP_(—)001552081.1, XP_(—)003066638.1, XP_(—)003176049.1, ACD75402.1, BAA05145.1, XP_(—)002482834.1, XP_(—)001257501.1, XP_(—)001934574.1, XP_(—)001269972.1, XP_(—)001587438.1, XP_(—)001215856.1, XP_(—)002149824.1, XP_(—)001550556.1, XP_(—)003011982.1, XP_(—)001827121.1, XP_(—)003233566.1, XP_(—)003022481.1, EGR47044.1, EFQ34695.1, XP_(—)003170005.1, BAG09241.1, XP_(—)002796370.1, XP_(—)003019300.1, XP_(—)002563873.1, CAK40654.1, EEH19741.1, XP_(—)003012518.1, EGD95716.1, XP_(—)003239409.1, BAJ04363.1, XP_(—)001537012.1, BAE66393.1, EGP85214.1, XP_(—)002487227.1, AAV66104.1, EGE07669.1, XP_(—)362943.2, XP_(—)003016806.1, EFQ27388.1, XP_(—)002384360.1, XP_(—)002836323.1, XP_(—)001274959.1, EFZ03093.1, XP_(—)661521.1, XP_(—)002849803.1, XP_(—)001589398.1, AAR99474.1, XP_(—)003189427.1, XP_(—)001823699.1, XP_(—)364111.1, XP_(—)001262753.1, EFY86805.1, XP_(—)001390153.2, XP_(—)002384738.1, XP_(—)001941811.1, XP_(—)001220831.1, XP_(—)003296981.1, XP_(—)002480829.1, BAD83681.1, XP_(—)001827526.2, XP_(—)369556.1, CAK38224.1, EFQ26532.1, XP_(—)002562328.1, XP_(—)001904540.1, EGO52476.1, XP_(—)002382002.1, XP_(—)001225874.1, XP_(—)958030.2, XP_(—)002540883.1, XP_(—)001908957.1, XP_(—)001559255.1, XP_(—)364102.1, EDP48064.1, XP_(—)365075.1, XP_(—)381460.1, CBX95930.1, XP_(—)003054099.1, XP_(—)361347.2, XP_(—)002846867.1, XP_(—)001214985.1, EFQ35175.1, XP_(—)002479062.1, XP_(—)001908613.1, XP_(—)003345380.1, EGR50567.1, XP_(—)002479350.1, XP_(—)001394417.2, XP_(—)001394159.2, XP_(—)002146776.1, EGP86783.1, EFX02953.1, CAK45889.1, XP_(—)003006887.1, XP_(—)002541427.1, XP_(—)750735.1, XP_(—)001257962.1, EGO51720.1, XP_(—)003005336.1, EGP83197.1, XP_(—)002149832.1, XP_(—)003052680.1, XP_(—)365851.1, XP_(—)001799910.1, XP_(—)003347175.1, XP_(—)002565258.1, EGR48918.1, EGR52524.1, XP_(—)964653.2, XP_(—)002147083.1, XP_(—)002843935.1, EEH19393.1, CAC10088.1, EEH47609.1, EEQ92528.1, XP_(—)001246560.1, XP_(—)002626168.1, XP_(—)003024880.1, XP_(—)003169255.1, XP_(—)003013780.1, XP_(—)003235691.1, XP_(—)746816.1, EGD98483.1, XP_(—)001389925.2, XP_(—)002842817.1, XP_(—)002797278.1, ADK36666.1, XP_(—)003305469.1, XP_(—)001548471.1, XP_(—)001806478.1, EFQ34989.1, XP_(—)001552987.1, CAC24473.1, XP_(—)002541530.1, EEQ89262.1, XP_(—)001247332.1, XP_(—)003066043.1, EDP47672.1, XP_(—)002628451.1, XP_(—)001910644.1, EGR44510.1, EFQ36733.1, XP_(—)003052472.1, XP_(—)001393445.2, XP_(—)001522438.1, EGO04179.1, XP_(—)001397944.2, CAK49049.1, EFQ30109.1, XP_(—)001585052.1, EGO30123.1, XP_(—)388496.1, XP_(—)003173913.1, CBF76609.1, XP_(—)003028593.1, EGO04180.1, CAK46976.1, XP_(—)370476.1, XP_(—)002145942.1, XP_(—)003004457.1, ADK36663.1, XP_(—)003040708.1, XP_(—)003351473.1, EFY84692.1, XP_(—)748328.2, XP_(—)003190325.1, XP_(—)002378813.1, EGR46513.1, XP_(—)003033448.1, XP_(—)002145326.1, XP_(—)662462.1, XP_(—)747469.1, XP_(—)001935085.1, EGR45892.1, EGO01601.1, EGP89995.1, XP_(—)001222615.1, XP_(—)001224356.1, EGN93507.1, XP_(—)001934479.1, BAK09464.1, EGO30124.1, XP_(—)001267956.1, ADK36661.1, EFY97845.1, XP_(—)001834501.1, EGO03790.1, XP_(—)001884320.1, XP_(—)003028899.1, AAP79879.1, EFY84206.1, BAK09467.1, XP_(—)003030469.1, XP_(—)001412594.1, XP_(—)001834508.1, XP_(—)001839436.2, XP_(—)002583529.1, XP_(—)001886288.1, XP_(—)002843371.1, XP_(—)001587730.1, BAK09418.1, BAK09442.1, EGO28830.1, EGE03365.1, EFZ01428.1, EGO03065.1, XP_(—)001558890.1, XP_(—)002487181.1, EGO29652.1, AAX49400.1, EFY92529.1, XP_(—)002380252.1, XP_(—)001884460.1, BAK09387.1, XP_(—)001839366.2, XP_(—)003031835.1, EFY99978.1, AAL67906.1, BAG09240.1, XP_(—)002381768.1, XP_(—)001800031.1, XP_(—)001825073.2, BAE63940.1, XP_(—)003028894.1, AAL67905.1, XP_(—)002910303.1, EGO22856.1, XP_(—)003028896.1, XP_(—)681680.1, XP_(—)002486603.1, XP_(—)001838945.2, EGR50064.1, XP_(—)001884349.1, XP_(—)001883816.1, CAK37996.1, CAO91865.1, XP_(—)003031227.1, XP_(—)001258702.1, XP_(—)001586739.1, XP_(—)001560806.1, CBF69707.1, ADN43682.1, XP_(—)001593179.1, XP_(—)001886909.1, XP_(—)001934479.1, XP_(—)001587730.1, XP_(—)001886909.1, XP_(—)001831709.2, XP_(—)001392650.1, XP_(—)366716.2, CAL69594.1, XP_(—)001269140.1, XP_(—)002566307.1, XP_(—)001555473.1, XP_(—)663925.1, XP_(—)001598033.1, XP_(—)001835239.2, EGN97256.1, XP_(—)001554305.1, NP_(—)182075.1, XP_(—)001560475.1, EFQ32286.1, XP_(—)001216788.1, XP_(—)002483975.1, AAC31835.1, NP_(—)850427.1, XP_(—)002143660.1, XP_(—)003327130.1, BAJ78287.1, XP_(—)002880182.1, ACB59278.1, EFQ36688.1, BAJ78285.1, BAJ78286.1, XP_(—)001798699.1, EEH44101.1, BAJ78288.1, BAJ78284.1, EGG02425.1, EGG03011.1, AAA34334.1, NP_(—)001189747.1, EGG02601.1, XP_(—)002978645.1, EGG11203.1, XP_(—)762610.1, XP_(—)762620.1, XP_(—)001545581.1, CAB44684.1, CAN80536.1, AAN05337.1, NP_(—)001049423.1, XP_(—)001791898.1, NP_(—)001031814.1, XP_(—)002279531.1, ABK94777.1, AAZ39646.1, XP_(—)002880183.1, ABC68403.1, XP_(—)002839066.1, EGG03014.1, XP_(—)002320074.1, NP_(—)001182854.1, CBI38795.3, XP_(—)002310605.1, NP_(—)196442.2, XP_(—)002270594.1, ABZ80830.1, XP_(—)002275905.1, CBI38796.3, XP_(—)002476978.1, CAB93726.1, EGG03624.1, EGG06527.1, NP_(—)197710.1, XP_(—)001768338.1, XP_(—)002270673.1, BAJ86572.1, XP_(—)002275806.1, CBI38797.3, XP_(—)002320072.1, CAN60189.1, XP_(—)002986290.1, XP_(—)002465888.1, CAN80040.1, XP_(—)002336104.1, XP_(—)002988354.1, XP_(—)002264277.1, EGD72898.1, XP_(—)002866853.1, EAY95236.1, XP_(—)002979701.1, XP_(—)002988762.1, XP_(—)002304502.1, XP_(—)002873349.1, XP_(—)003192947.1, CAN63571.1, NP_(—)001053615.1, NP_(—)176558.1, EGC49561.1, EGG09027.1, XP_(—)002314581.1, XP_(—)002446966.1, XP_(—)002320802.1, ABC59095.1, XP_(—)003323121.1, XP_(—)002974639.1, XP_(—)002395587.1, XP_(—)002866852.1, XP_(—)002319770.1, NP_(—)001146262.1, NP_(—)001169224.1, AAM65207.1, XP_(—)002529058.1, XP_(—)002886391.1, XP_(—)002320071.1, XP_(—)002446967.1, XP_(—)757870.1, EAY95147.1, XP_(—)002899664.1, EEH05830.1, XP_(—)002874114.1, ADO24345.1, BAJ88802.1, BAA05146.1, XP_(—)002963351.1, EAY88475.1, NP_(—)195658.3, XP_(—)002976944.1, ABC59093.1, XP_(—)002275114.1, XP_(—)003328407.1, CAN75428.1, BAJ86471.1, XP_(—)002981144.1, XP_(—)002277006.1, EAZ26110.1, ACN41008.1, XP_(—)002899542.1, XP_(—)001781614.1, EAY76187.1, BAK06758.1, XP_(—)002511745.1, XP_(—)002982626.1, XP_(—)002963763.1, NP_(—)001065111.1, ABF93892.1, XP_(—)002314117.1, BAK06287.1, XP_(—)001745327.1, NP_(—)001047674.1, XP_(—)002878665.1, XP_(—)002974847.1, NP_(—)179899.1, CAN80156.1, NP_(—)001053543.1, ABC59094.1, XP_(—)002328165.1, XP_(—)002270628.1, XP_(—)002275115.1, XP_(—)002980688.1, XP_(—)002465039.1, AAL91155.1, NP_(—)195910.1, XP_(—)002509820.1, NP_(—)200694.1, CAA62082.1, AAL75903.1, XP_(—)002468241.1, XP_(—)002883546.1, XP_(—)002862636.1, XP_(—)002312905.1, EAY79269.1, AAM12494.1, XP_(—)002875027.1, XP_(—)758010.1, XP_(—)002509524.1, AAP54707.2, XP_(—)002869292.1, NP_(—)001143079.1, ACF82946.1, XP_(—)002270497.1, XP_(—)002979685.1, XP_(—)002465041.1, XP_(—)002533544.1, AAG17470.1, XP_(—)002985393.1, NP_(—)191946.1, XP_(—)002525608.1, AAZ39642.1, XP_(—)002270428.1, XP_(—)002529227.1, CBI24485.3, XP_(—)001763206.1, EGG02922.1, XP_(—)002974848.1, NP_(—)001141467.1, CBI27149.3, NP_(—)001130907.1, XP_(—)002982474.1, NP_(—)001048917.1, XP_(—)002465889.1, ABZ80831.1, XP_(—)002464461.1, EAY88476.1, BAJ90714.1, XP_(—)002893825.1, ACN28568.1, XP_(—)002452782.1, XP_(—)002280004.1, XP_(—)001764611.1, NP_(—)001183394.1, BAJ89570.1, CBI24484.3, BAJ88840.1, ACG38359.1, CAN77648.1, BAJ91452.1, NP_(—)001141345.1, XP_(—)002282185.1, XP_(—)002980994.1, XP_(—)002299820.1, BAJ87982.1, BAJ91842.1, XP_(—)003325270.1, XP_(—)001760399.1, CBI34058.3, ADG34845.1, XP_(—)002523775.1, EEH21852.1, Q50EK3.1, BAK06748.1, XP_(—)002963764.1, ACN34158.1, XP_(—)001764503.1, XP_(—)002311750.1, XP_(—)001782495.1, XP_(—)002988642.1, XP_(—)002465625.1, XP_(—)002892051.1, XP_(—)002279649.1, NP_(—)171666.1, ABK28430.1, BAC42067.1, AED99869.1, NP_(—)174713.1, XP_(—)001781706.1, ABG66204.1, XP_(—)002964775.1, NP_(—)001064901.2, XP_(—)002961706.1, XP_(—)002519477.1, XP_(—)001559854.1, CBH32594.1, BAB92258.1, XP_(—)002264897.1, AAL59025.1, XP_(—)002862576.1, ACL53124.1, XP_(—)002521476.1, NP_(—)200045.1, BAJ89814.1, CBI38794.3, XP_(—)776769.1, NP_(—)001141372.1, EEC74485.1, EAY76557.1, XP_(—)002318861.1, NP_(—)001172660.1, XP_(—)002880978.1, AAO00706.1, BAK07606.1, XP_(—)002979336.1, BAC42841.1, BAF46296.1, XP_(—)002306380.1, XP_(—)002865907.1, ACG34921.1, XP_(—)002876375.1, NP_(—)001056685.1, XP_(—)002264292.1, XP_(—)002893443.1, NP_(—)001066096.1, EEE53477.1, CBH32607.1, EAY94753.1, NP_(—)001130939.1, NP_(—)182121.1, XP_(—)002437749.1, NP_(—)191222.1, XP_(—)002865881.1, XP_(—)569708.1, XP_(—)002279670.1, BAJ94774.1, ABF93894.1, BAD94304.1, ACG33785.1, NP_(—)194944.1, NP_(—)180337.1, AAB63277.1, BAJ85246.1, XP_(—)002456654.1, ACN27732.1, XP_(—)002445325.1, EER40289.1, XP_(—)001838184.2, BAJ85532.1, XP_(—)002866555.1, EAY88477.1, ACG47870.1, XP_(—)002310074.1, XP_(—)002457224.1, EAZ25521.1, BAJ87689.1, NP_(—)001044838.1, XP_(—)002521004.1, XP_(—)002882043.1, XP_(—)002527038.1, XP_(—)002318721.1, XP_(—)002979339.1, NP_(—)176086.1, XP_(—)001560028.1, ABC59092.1, ABF93891.1, ACR38435.1, EAY78983.1, NP_(—)179782.1, CCA21696.1, XP_(—)002334340.1, EFX88387.1, NP_(—)001044554.1, XP_(—)002321857.1, NP_(—)173862.1, NP_(—)195660.1, XP_(—)001554079.1, EAZ13864.1, EEC67630.1, EAY76183.1, AAP54710.2, NP_(—)001065112.2, ACD10924.1, XP_(—)001559275.1, EEC67338.1, XP_(—)002273811.1, ADJ68242.1, NP_(—)001065698.1, CAN66874.1, CAB41474.1, XP_(—)002868908.1, XP_(—)002904660.1, CAR47816.1, NP_(—)189243.1, EAY98229.1, XP_(—)002448320.1, O81117.2, XP_(—)002458797.1, XP_(—)002277129.1, BAJ88829.1, CAN67559.1, BAK08034.1, XP_(—)002894062.1, XP_(—)002894891.1, XP_(—)002279981.1, ABR16451.1, NP_(—)201150.1, AAM60854.1, XP_(—)002521002.1, XP_(—)002521474.1, XP_(—)002875311.1, NP_(—)195661.1, AAP79889.1, NP_(—)175193.1, P98188.1, BAK08270.1, CBI21357.3, XP_(—)002870817.1, XP_(—)002904451.1, ABA95812.1, XP_(—)002998647.1, NP_(—)001066166.2, XP_(—)002894690.1, EFY92064.1, XP_(—)002278009.1, XP_(—)002336002.1, CCA16508.1, XP_(—)002868909.1, EAZ31703.1, C96517, EAY86526.1, XP_(—)002307954.1, XP_(—)002904638.1, XP_(—)002266883.1, XP_(—)002439880.1, XP_(—)002892730.1, ADI52567.1, EGI61791.1, XP_(—)002511196.1, EGG04372.1, XP_(—)002511875.1, ACE75189.1, NP_(—)001055681.1, XP_(—)001589816.1, NP_(—)001170655.1, XP_(—)002300789.1, XP_(—)001934479.1, XP_(—)001587730.1, XP_(—)001554079.1, XP_(—)001559275.1, XP_(—)002868908.1, XP_(—)002998647.1, EFY92064.1, XP_(—)002605799.1, BAC43393.1, ABK28457.1, AAL54887.1, BAC43161.1, XP_(—)002333384.1, ZP_(—)03631129.1, AAL84318.1, BAJ99856.1, XP_(—)002593704.1, YP_(—)001965159.1, XP_(—)002454121.1, EFX88390.1, ABR16969.1, NP_(—)177109.3, XP_(—)002441724.1, NP_(—)001166017.1, BAB92256.1, ACE75340.1, AAZ39645.1, XP_(—)002312417.1, XP_(—)002887239.1, NP_(—)001172609.1, NP_(—)001065766.1, XP_(—)002515053.1, AAL54885.1, ABR16897.1, XP_(—)002878579.1, NP_(—)001140775.1, XP_(—)003275955.1, ZP_(—)08045694.1, BAJ94069.1, XP_(—)001654558.1, XP_(—)002436562.1, EAY88702.1, BAK03685.1, XP_(—)003327629.1, XP_(—)002322606.1, EEH42702.1, XP_(—)002037976.1, NP_(—)172774.1, XP_(—)002282477.1, EFX88388.1, XP_(—)002522465.1, EFZ21470.1, AAO41955.1, AAL54886.1, XP_(—)002450277.1, XP_(—)002862559.1, XP_(—)002335046.1, XP_(—)003328408.1, ACE75187.1, XP_(—)001849294.1, XP_(—)002444132.1, XP_(—)002894061.1, EFN77015.1, EGI69992.1, CBI17962.3, AAL54884.1, XP_(—)002998650.1, XP_(—)002105150.1, XP_(—)002877615.1, EFZ22412.1, XP_(—)002439815.1, XP_(—)002300790.1, CBI40391.3, AEI59774.1, XP_(—)002801151.1, XP_(—)003325267.1, XP_(—)001554577.1, EAY79865.1, XP_(—)002465796.1, XP_(—)002931035.1, ABA91371.1, ACE75338.1, XP_(—)001592850.1, XP_(—)001362981.1, XP_(—)002271246.1, EGB11905.1, NP_(—)176713.1, CBJ27248.1, NP_(—)566155.1, EFX87732.1, EEC71661.1, ACG29046.1, NP_(—)001130576.1, XP_(—)001843663.1, ABK25134.1, EGI65081.1, XP_(—)002722841.1, AAL67908.2, AAO15579.1, YP_(—)122047.1, EFA04617.1, YP_(—)001522424.1, ACB87383.1, NP_(—)001027517.1, EEE52725.1, XP_(—)002078257.1, XP_(—)002722842.1, ZP_(—)05128707.1, XP_(—)003208874.1, AAK31592.1, ABA95747.2, NP_(—)001181472.1, NP_(—)001075572.1, XP_(—)001108915.1, XP_(—)001520882.1, XP_(—)002063219.1, EFZ22408.1, AAL57721.1, EFW47740.1, AAQ20834.1, CAN74644.1, XP_(—)002722849.1, BAC30028.1, CAN75729.1, XP_(—)002115603.1, AAN72309.1, EEC68823.1, CAM18519.1, EAZ13863.1, XP_(—)002906159.1, NP_(—)001003947.1, ZP_(—)01858832.1, XP_(—)002882162.1, XP_(—)002089195.1, XP_(—)002892729.1, CAN68037.1, NP_(—)001130648.1, NP_(—)001166016.1, NP_(—)172773.4, ADJ68241.1, EGI62551.1, EFN63658.1, XP_(—)002300103.1, XP_(—)001658673.1, XP_(—)001367719.1, NP_(—)775146.1, XP_(—)001375048.1, AAH21377.1, NP_(—)727589.1, XP_(—)002271847.1, XP_(—)001809620.1, XP_(—)002897528.1, NP_(—)190421.1, XP_(—)002282468.1, XP_(—)536868.2, EEE58297.1, XP_(—)001992105.1, EAY82190.1, ADD20161.1, XP_(—)001363065.1, EAU77129.3, EAY72807.1, EGG03077.1, NP_(—)001181489.1, NP_(—)001177869.1, XP_(—)001966135.1, BAA99522.1, BAK07250.1, XP_(—)002133118.1, NP_(—)001042228.1, AAL57720.1, XP_(—)002897529.1, AAA35712.1, YP_(—)002275016.1, NP_(—)000770.2, XP_(—)002721578.1, XP_(—)321208.4, AAM09532.1, EFN61085.1, BAK06179.1, EFX88389.1, YP_(—)001602608.1, XP_(—)513140.3, NP_(—)001182438.1, AAD31068.1, NP_(—)001093242.1, XP_(—)001367758.2, EFZ18984.1, YP_(—)691921.1, CAH59968.1, AAS80270.1, CAH59967.1, ACQ99381.2, YP_(—)003810988.1, YP_(—)957888.1, CBW44755.1, ZP_(—)05042596.1, ZP_(—)01913735.1, ZP_(—)05043097.1, ADQ00145.1, YP_(—)004494060.1, ZP_(—)08206912.1, BAE78452.1, NP_(—)114222.1, ACZ56357.1, YP_(—)640381.1, ZP_(—)04384919.1, ZP_(—)08025219.1, ZP_(—)07715822.1, ZP_(—)06847816.1, YP_(—)001702784.1, AEK27137.1, ZP_(—)07716433.1, ZP_(—)08199554.1, YP_(—)004495520.1, YP_(—)345718.1, ZP_(—)08022914.1, YP_(—)001851443.1, BAG50428.1, YP_(—)001135848.1, BAF95905.1, YP_(—)345695.1, ACP39691.1, ACP39664.1, ACP39635.1, ACP39633.1, ACP39710.1, ACP39698.1, ACP39711.1, BAE47475.1, BAE47474.1, ABW76858.1, ACO50699.1, ACP39643.1, ACP39639.1, ACP39708.1, ACM68663.1, ACP39642.1, ACP39684.1, ACP39636.1, ZP_(—)05095005.1, ACP39652.1, BAE47473.1, ACM68664.1, ACP39646.1, ACP39680.1, ACP39692.1, ACP39675.1, ACP39632.1, ZP_(—)05129284.1, ACP39706.1, ACP39695.1, ACM68665.1, ACP39654.1, ACP39665.1, ACP39649.1, BAE47472.1, ACM68668.1, ACP39676.1, ACP39648.1, ACP39647.1, ZP_(—)01102434.1, ACM68666.1, ACP39641.1, ACM68669.1, ZP_(—)01625037.1, ACP39690.1, ACP39696.1, ACP39697.1, ACP39707.1, ACP39682.1, ACP39650.1, ACP39638.1, ZP_(—)05126641.1, CAH04396.1, ACP39658.1, ZP_(—)01102687.1, ACJ06772.1, YP_(—)001413041.1, YP_(—)552058.1, ADE05601.1, ADI19685.1, BAE47479.1, ZP_(—)01626700.1, ZP_(—)01618279.1, CAH61448.1, YP_(—)001411305.1, YP_(—)003591161.1, ZP_(—)01615522.1, ACM68667.1, ACP39651.1, ZP_(—)05095535.1, ZP_(—)01618489.1, NP_(—)418882.1, ADI19983.1, ACP39677.1, BAE47476.1, ACP39655.1, ACP39656.1, ADI19696.1, BAE47477.1, YP_(—)001413399.1, YP_(—)459878.1, BAE47480.1, BAE47481.1, ACP39653.1, BAE47478.1, YP_(—)001681656.1, ZP_(—)01618281.1, ZP_(—)01627262.1, YP_(—)001413057.1, YP_(—)760740.1, YP_(—)001242466.1, YP_(—)001203574.1, CAH61454.1, YP_(—)002129656.1, YP_(—)001672075.1, ACP39709.1, YP_(—)001990805.1, NP_(—)946959.1, YP_(—)001203575.1, YP_(—)783213.1, YP_(—)003059227.1, YP_(—)004110202.1, ACP39645.1, YP_(—)487538.1, CAH61451.1, YP_(—)570816.1, YP_(—)534107.1, YP_(—)001413223.1, YP_(—)001242465.1, YP_(—)557448.1, ZP_(—)08631162.1, NP_(—)773883.1, ZP_(—)00997728.1, ACP39683.1, NP_(—)768493.1, NP_(—)773882.1, ZP_(—)08271781.1, CAH61449.1, YP_(—)003883668.1, YP_(—)003332953.1, YP_(—)004535688.1, YP_(—)495502.1, YP_(—)459378.1, ZP_(—)08700267.1, ZP_(—)01863452.1, ZP_(—)06860085.1, BAE47487.1, YP_(—)617903.1, ZP_(—)08207422.1, BAE47486.1, ZP_(—)01041003.1, BAE47484.1, ACR78197.1, CAH61456.1, ZP_(—)01858113.1, ACP39681.1, BAE47485.1, ACP39673.1, BAE47483.1, ACP39669.1, BAE47482.1, ACP39674.1, ACP39704.1, ACP39703.1, YP_(—)497095.1, ACP39672.1, ACP39702.1, ACP39670.1, ACP39666.1, YP_(—)458852.1, ACP39687.1, ACP39688.1, ACP39634.1, ACP39686.1, ACP39660.1, ACP39700.1, YP_(—)001411309.1, ZP_(—)01465241.1, ACP39701.1, ACP39679.1, ACP39657.1, ACP39694.1, ACP39659.1, ACP39671.1, ACP39693.1 and YP_(—)003342921.1, in particular AAO73954.1, AAO73953.1, XP_(—)002546279.1, AAA34353.2, P30607.1, XP_(—)002421627.1, XP_(—)718670.1, CAA39366.1, XP_(—)001527524.1, AAO73955.1, AAO73956.1, XP_(—)002546278.1, EEQ43157.1, XP_(—)718669.1, AAA34354.1, P10615.3, XP_(—)002421628.1, 226487, P16141.3, CAA39367.1, Q9Y757.2, XP_(—)001485567.1, AAO73958.1, XP_(—)001383506.2, XP_(—)460111.2, AAO73959.1, Q12586.1, XP_(—)460112.2, AAO73960.1, Q12589.1, AAO73961.1, XP_(—)460110.2, EEQ43763.1, XP_(—)710174.1, EDK41572.2, XP_(—)001482650.1, CAA75058.1, XP_(—)002548818.1, Q12588.1, XP_(—)002422222.1, XP_(—)001383636.2, XP_(—)001525381.1, XP_(—)002548823.1, P30610.1, AAO73952.1, XP_(—)002548428.1, CAA36197.1, XP_(—)002421126.1, AAA34320.1, P16496.3, P30608.1, P24458.1, XP_(—)717999.1, XP_(—)001383817.1, Q9Y758.1, XP_(—)001482092.1, XP_(—)001383710.2, P30609.1, AAB24479.1, XP_(—)457792.1, XP_(—)001524144.1, XP_(—)457727.2, XP_(—)001525578.1, XP_(—)002616743.1, XP_(—)002614836.1, XP_(—)001525577.1, AAO73957.1, Q12585.1, XP_(—)001386440.2, XP_(—)002616857.1, XP_(—)001483276.1, XP_(—)500402.1, EDK39907.2, XP_(—)500560.1, XP_(—)001211376.1, XP_(—)002560027.1, XP_(—)504857.1, XP_(—)500855.1, XP_(—)504406.1, BAA31433.1, XP_(—)500856.1, XP_(—)501148.1, XP_(—)746567.1, XP_(—)001262425.1, XP_(—)001274843.1, XP_(—)002840588.1, XP_(—)002377641.1, XP_(—)001825995.1, XP_(—)001400739.1, XP_(—)718066.1, CAA35593.1, XP_(—)664735.1, XP_(—)002150795.1, XP_(—)500097.1, XP_(—)002483325.1, XP_(—)504311.1, XP_(—)500273.1, XP_(—)002548817.1, EDP54484.1, XP_(—)755288.1, XP_(—)001260447.1, EFY97851.1, ACD75398.1, ADK36660.1, XP_(—)001213081.1, XP_(—)002377989.1, XP_(—)001826299.1, XP_(—)001554811.1, XP_(—)501667.1, XP_(—)002148942.1, ADK36662.1, XP_(—)002565827.1, P30611.1, XP_(—)001267871.1, XP_(—)002372373.1, EFY84686.1, P43083.1, XP_(—)001263094.1, XP_(—)002148355.1, XP_(—)002568429.1, XP_(—)001817314.1, Q12587.1, XP_(—)001396435.1, XP_(—)001938589.1, XP_(—)001388497.2, XP_(—)663661.1, XP_(—)003295335.1, XP_(—)002152088.1, XP_(—)001212071.1, Q12573.1, XP_(—)002379858.1, XP_(—)001821592.1, XP_(—)002844341.1, XP_(—)001394678.1, ACD75400.1, XP_(—)003170343.1, XP_(—)001265480.1, XP_(—)002550661.1, EDP55514.1, XP_(—)001528842.1, XP_(—)749919.1, XP_(—)001593058.1, P30612.1, EGC48494.1, EEH04429.1, XP_(—)001585586.1, XP_(—)003236182.1, XP_(—)001400199.1, EEQ46951.1, XP_(—)721410.1, EGP87864.1, XP_(—)002380808.1, XP_(—)001792771.1, XP_(—)001208515.1, XP_(—)001216161.1, XP_(—)003071804.1, EFW16963.1, XP_(—)002542118.1, XP_(—)001936677.1, EGD95268.1, XP_(—)003015678.1, XP_(—)501748.1, XP_(—)003169562.1, EFY96492.1, XP_(—)682653.1, XP_(—)002421356.1, CAK43439.1, EFY93677.1, XP_(—)747767.1, XP_(—)001244958.1, XP_(—)003019635.1, XP_(—)002847463.1, EGP83273.1, EGR52487.1, XP_(—)002622526.1, XP_(—)002563618.1, CBX99718.1, XP_(—)001552081.1, XP_(—)003066638.1, XP_(—)003176049.1, ACD75402.1, BAA05145.1, XP_(—)002482834.1, XP_(—)001257501.1, XP_(—)001934574.1, XP_(—)001269972.1, XP_(—)001587438.1, XP_(—)001215856.1, XP_(—)002149824.1, XP_(—)001550556.1, XP_(—)003011982.1, XP_(—)001827121.1, XP_(—)003233566.1, XP_(—)003022481.1, EGR47044.1, EFQ34695.1, XP_(—)003170005.1, BAG09241.1, XP_(—)002796370.1, XP_(—)003019300.1, XP_(—)002563873.1, CAK40654.1, EEH19741.1, XP_(—)003012518.1, EGD95716.1, XP_(—)003239409.1, BAJ04363.1, XP_(—)001537012.1, BAE66393.1, EGP85214.1, XP_(—)002487227.1, AAV66104.1, EGE07669.1, XP_(—)362943.2, XP_(—)003016806.1, EFQ27388.1, XP_(—)002384360.1, XP_(—)002836323.1, XP_(—)001274959.1, EFZ03093.1, XP_(—)661521.1, XP_(—)002849803.1, XP_(—)001589398.1, AAR99474.1, XP_(—)003189427.1, XP_(—)001823699.1, XP_(—)364111.1, XP_(—)001262753.1, EFY86805.1, XP_(—)001390153.2, XP_(—)002384738.1, XP_(—)001941811.1, XP_(—)001220831.1, XP_(—)003296981.1, XP_(—)002480829.1, BAD83681.1, XP_(—)001827526.2, XP_(—)369556.1, CAK38224.1, EFQ26532.1, XP_(—)002562328.1, XP_(—)001904540.1, EGO52476.1, XP_(—)002382002.1, XP_(—)001225874.1, XP_(—)958030.2, XP_(—)002540883.1, XP_(—)001908957.1, XP_(—)001559255.1, XP_(—)364102.1, EDP48064.1, XP_(—)365075.1, XP_(—)381460.1, CBX95930.1, XP_(—)003054099.1, XP_(—)361347.2, XP_(—)002846867.1, XP_(—)001214985.1, EFQ35175.1, XP_(—)002479062.1, XP_(—)001908613.1, XP_(—)003345380.1, EGR50567.1, XP_(—)002479350.1, XP_(—)001394417.2, XP_(—)001394159.2, XP_(—)002146776.1, EGP86783.1, EFX02953.1, CAK45889.1, XP_(—)003006887.1, XP_(—)002541427.1, XP_(—)750735.1, XP_(—)001257962.1, EGO51720.1, XP_(—)003005336.1, EGP83197.1, XP_(—)002149832.1, XP_(—)003052680.1, XP_(—)365851.1, XP_(—)001799910.1, XP_(—)003347175.1, XP_(—)002565258.1, EGR48918.1, EGR52524.1, XP_(—)964653.2, XP_(—)002147083.1, XP_(—)002843935.1, EEH19393.1, CAC10088.1, EEH47609.1, EEQ92528.1, XP_(—)001246560.1, XP_(—)002626168.1, XP_(—)003024880.1, XP_(—)003169255.1, XP_(—)003013780.1, XP_(—)003235691.1, XP_(—)746816.1, EGD98483.1, XP_(—)001389925.2, XP_(—)002842817.1, XP_(—)002797278.1, ADK36666.1, XP_(—)003305469.1, XP_(—)001548471.1, XP_(—)001806478.1, EFQ34989.1, XP_(—)001552987.1, CAC24473.1, XP_(—)002541530.1, EEQ89262.1, XP_(—)001247332.1, XP_(—)003066043.1, EDP47672.1, XP_(—)002628451.1, XP_(—)001910644.1, EGR44510.1, EFQ36733.1, XP_(—)003052472.1, XP_(—)001393445.2, XP_(—)001522438.1, XP_(—)001397944.2, CAK49049.1, EFQ30109.1, XP_(—)001585052.1, XP_(—)388496.1, XP_(—)003173913.1, CBF76609.1, CAK46976.1, XP_(—)370476.1, XP_(—)002145942.1, XP_(—)003004457.1, ADK36663.1, XP_(—)003040708.1, XP_(—)003351473.1, EFY84692.1, XP_(—)748328.2, XP_(—)003190325.1, XP_(—)002378813.1, EGR46513.1, XP_(—)002145326.1, XP_(—)662462.1, XP_(—)747469.1, XP_(—)001935085.1, EGR45892.1, EGP89995.1, XP_(—)001222615.1, XP_(—)001224356.1, XP_(—)001934479.1, XP_(—)001267956.1, ADK36661.1, EFY97845.1, EFY84206.1, XP_(—)001412594.1, XP_(—)002583529.1, XP_(—)002843371.1, XP_(—)001587730.1, EGE03365.1, EFZ01428.1, XP_(—)001558890.1, XP_(—)002487181.1, EFY92529.1, XP_(—)002380252.1, EFY99978.1, BAG09240.1, XP_(—)002381768.1, XP_(—)001800031.1, XP_(—)001825073.2, BAE63940.1, XP_(—)681680.1, XP_(—)002486603.1, EGR50064.1, CAK37996.1, CAO91865.1, XP_(—)001258702.1, XP_(—)001586739.1, XP_(—)001560806.1, CBF69707.1, ADN43682.1, XP_(—)001593179.1, XP_(—)001392650.1, XP_(—)366716.2, CAL69594.1, XP_(—)001269140.1, XP_(—)002566307.1, XP_(—)001555473.1, XP_(—)663925.1, XP_(—)001598033.1, XP_(—)001554305.1, XP_(—)001560475.1, EFQ32286.1, XP_(—)001216788.1, XP_(—)002483975.1, XP_(—)002143660.1, EFQ36688.1, XP_(—)001798699.1, EEH44101.1, AAA34334.1, XP_(—)001545581.1, XP_(—)001791898.1, XP_(—)002839066.1, EGC49561.1, EEH05830.1, BAA05146.1, EEH21852.1, XP_(—)001559854.1, EER40289.1, XP_(—)001560028.1, XP_(—)001554079.1, XP_(—)001559275.1, EFY92064.1, XP_(—)001589816.1, EEH42702.1, XP_(—)001554577.1, XP_(—)001592850.1, YP_(—)691921.1, CAH59968.1, AAS80270.1, CAH59967.1, ACQ99381.2, YP_(—)003810988.1, YP_(—)957888.1, CBW44755.1, ZP_(—)05042596.1, ZP_(—)01913735.1, ZP_(—)05043097.1, ADQ00145.1, YP_(—)004494060.1, ZP_(—)08206912.1, BAE78452.1, NP_(—)114222.1, ACZ56357.1, YP_(—)640381.1, ZP_(—)04384919.1, ZP_(—)08025219.1, ZP_(—)07715822.1, ZP_(—)06847816.1, YP_(—)001702784.1, AEK27137.1, ZP_(—)07716433.1, ZP_(—)08199554.1, YP_(—)004495520.1, YP_(—)345718.1, ZP_(—)08022914.1, YP_(—)001851443.1, BAG50428.1, YP_(—)001135848.1, BAF95905.1, YP_(—)345695.1, ACP39691.1, ACP39664.1, ACP39635.1, ACP39633.1, ACP39710.1, ACP39698.1, ACP39711.1, BAE47475.1, BAE47474.1, ABW76858.1, ACO50699.1, ACP39643.1, ACP39639.1, ACP39708.1, ACM68663.1, ACP39642.1, ACP39684.1, ACP39636.1, ZP_(—)05095005.1, ACP39652.1, BAE47473.1, ACM68664.1, ACP39646.1, ACP39680.1, ACP39692.1, ACP39675.1, ACP39632.1, ZP_(—)05129284.1, ACP39706.1, ACP39695.1, ACM68665.1, ACP39654.1, ACP39665.1, ACP39649.1, BAE47472.1, ACM68668.1, ACP39676.1, ACP39648.1, ACP39647.1, ZP_(—)01102434.1, ACM68666.1, ACP39641.1, ACM68669.1, ZP_(—)01625037.1, ACP39690.1, ACP39696.1, ACP39697.1, ACP39707.1, ACP39682.1, ACP39650.1, ACP39638.1, ZP_(—)05126641.1, CAH04396.1, ACP39658.1, ZP_(—)01102687.1, ACJ06772.1, YP_(—)001413041.1, YP_(—)552058.1, ADE05601.1, ADI19685.1, BAE47479.1, ZP_(—)01626700.1, ZP_(—)01618279.1, CAH61448.1, YP_(—)001411305.1, YP_(—)003591161.1, ZP_(—)01615522.1, ACM68667.1, ACP39651.1, ZP_(—)05095535.1, ZP_(—)01618489.1, NP_(—)418882.1, ADI19983.1, ACP39677.1, BAE47476.1, ACP39655.1, ACP39656.1, ADI19696.1, BAE47477.1, YP_(—)001413399.1, YP_(—)459878.1, BAE47480.1, BAE47481.1, ACP39653.1, BAE47478.1, YP_(—)001681656.1, ZP_(—)01618281.1, ZP_(—)01627262.1, YP_(—)001413057.1, YP_(—)760740.1, YP_(—)001242466.1, YP_(—)001203574.1, CAH61454.1, YP_(—)002129656.1, YP_(—)001672075.1, ACP39709.1, YP_(—)001990805.1, NP_(—)946959.1, YP_(—)001203575.1, YP_(—)783213.1, YP_(—)003059227.1, YP_(—)004110202.1, ACP39645.1, YP_(—)487538.1, CAH61451.1, YP_(—)570816.1, YP_(—)534107.1, YP_(—)001413223.1, YP_(—)001242465.1, YP_(—)557448.1, ZP_(—)08631162.1, NP_(—)773883.1, ZP_(—)00997728.1 and particularly preferably AAO73954.1, AAO73953.1, XP_(—)002546279.1, AAA34353.2, P30607.1, XP_(—)002421627.1, XP_(—)718670.1, CAA39366.1, AAO73955.1, AAO73956.1, XP_(—)002546278.1, EEQ43157.1, XP_(—)718669.1, AAA34354.1, P10615.3, XP_(—)002421628.1, 226487, P16141.3, CAA39367.1, AAO73958.1, AAO73959.1, Q12586.1, AAO73960.1, Q12589.1, AAO73961.1, EEQ43763.1, XP_(—)710174.1, CAA75058.1, XP_(—)002548818.1, Q12588.1, XP_(—)002422222.1, XP_(—)002548823.1, P30610.1, AAO73952.1, XP_(—)002548428.1, CAA36197.1, XP_(—)002421126.1, AAA34320.1, P16496.3, P30608.1, P24458.1, XP_(—)717999.1, P30609.1, AAB24479.1, AAO73957.1, Q12585.1, XP_(—)718066.1, CAA35593.1, XP_(—)002548817.1, P30611.1, P43083.1, Q12587.1, Q12573.1, XP_(—)002550661.1, P30612.1, EEQ46951.1, XP_(—)721410.1, XP_(—)002421356.1, BAA05145.1, BAG09241.1, CAC24473.1, BAG09240.1, AAA34334.1, BAA05146.1, XP_(—)500402.1, XP_(—)500560.1, XP_(—)504857.1, XP_(—)500855.1, XP_(—)504406.1, BAA31433.1, XP_(—)500856.1, XP_(—)501148.1, XP_(—)500097.1, XP_(—)504311.1, XP_(—)500273.1, XP_(—)501667.1, XP_(—)501748.1, YP_(—)691921.1, CAH59968.1, AAS80270.1, CAH59967.1, ACQ99381.2, YP_(—)003810988.1, YP_(—)957888.1, CBW44755.1, ZP_(—)05042596.1, ZP_(—)01913735.1, ZP_(—)05043097.1, ADQ00145.1, YP_(—)004494060.1, ZP_(—)08206912.1, BAE78452.1, NP_(—)114222.1, ACZ56357.1, YP_(—)640381.1, ZP_(—)04384919.1, ZP_(—)08025219.1, ZP_(—)07715822.1, ZP_(—)06847816.1, YP_(—)001702784.1, AEK27137.1, ZP_(—)07716433.1, ZP_(—)08199554.1, YP_(—)004495520.1, YP_(—)345718.1, ZP_(—)08022914.1, YP_(—)001851443.1, BAG50428.1, YP_(—)001135848.1, BAF95905.1, YP_(—)345695.1, ACP39691.1, ACP39664.1, ACP39635.1, ACP39633.1, ACP39710.1, ACP39698.1, ACP39711.1, BAE47475.1, BAE47474.1, ABW76858.1, ACO50699.1, ACP39643.1, ACP39639.1, ACP39708.1, ACM68663.1, ACP39642.1, ACP39684.1, ACP39636.1, ZP_(—)05095005.1, ACP39652.1, BAE47473.1, ACM68664.1, ACP39646.1, ACP39680.1, ACP39692.1, ACP39675.1, ACP39632.1, ZP_(—)05129284.1, ACP39706.1, ACP39695.1, ACM68665.1, ACP39654.1, ACP39665.1, ACP39649.1, BAE47472.1, ACM68668.1, ACP39676.1, ACP39648.1, ACP39647.1, ZP_(—)01102434.1, ACM68666.1, ACP39641.1, ACM68669.1, ZP_(—)01625037.1, ACP39690.1, ACP39696.1, ACP39697.1, ACP39707.1, ACP39682.1, ACP39650.1 and ACP39638.1 and proteins with a polypeptide sequence wherein up to 60%, preferably up to 25%, particularly preferably up to 15%, in particular up to 10, 9, 8, 7, 6, 5, 4, 3, 2 or 1% of the amino acid residues are modified compared to the aforementioned reference sequences by deletion, insertion, substitution or a combination thereof and which still possess at least 50%, preferably 65%, particularly preferably 80%, in particular more than 90% of the activity of the protein with the corresponding, aforementioned reference sequence, wherein 100% activity of the reference protein is understood to mean the increasing of the activity of the cells used as a biocatalyst, i.e. the quantity of substance converted per unit time based on the cell quantity used (units per gram cell dry weight [U/g CDW]) in comparison to the activity of the biocatalyst in the absence of the reference protein, wherein the activity in this connection and in connection with the determination of the activity of the enzyme E_(1a) in general is understood to mean in particular the conversion of lauric acid and/or methyl laurate to ω-hydroxylauric acid and/or methyl ω-hydroxylaurate.

Modifications of amino acid residues of a given polypeptide sequence which lead to no significant modifications of the properties and function of the given polypeptide are known to those skilled in the art. Thus for example many amino acids can often be exchanged for one another without problems; examples of such suitable amino acid substitutions are: Ala by Ser; Arg by Lys; Asn by Gln or His; Asp by Glu; Cys by Ser; Gln by Asn; Glu by Asp; Gly by Pro; His by Asn or Gln; Ile by Leu or Val; Leu by Met or Val; Lys by Arg or Gln or Glu; Met by Leu or Ile; Phe by Met or Leu or Tyr; Ser by Thr; Thr by Ser; Trp by Tyr; Tyr by Trp or Phe; Val by Ile or Leu. It is also known that modifications, particularly at the N- or C-terminus of a polypeptide in the form of for example amino acid insertions or deletions, often exert no significant influence on the function of the polypeptide.

AlkB alkane hydroxylases preferred according to the invention are selected from the list

YP_(—)001185946.1, Q9WWW6.1, YP_(—)957898.1, YP_(—)957728.1, YP_(—)694427.1, BAC98365.1, ZP_(—)00957064.1, CAC86944.1, YP_(—)001672212.1, CAB59525.1, ACH99213.1, ACH99215.1, ACH99216.1, AAK56792.1, ACH99229.1, ACS91348.1, AAP41820.1, ZP_(—)05128075.1, CAM58121.1, CAM58085.1, ACQ44675.1, ACZ62808.1, ZP_(—)01738706.1, ZP_(—)01916228.1, ZP_(—)01225325.1, YP_(—)001023605.1, ACJ22747.1, ACT91140.1, AAT91722.2, CBA27418.1, YP_(—)001889129.1, EGC97932.1, ACT91201.1, ZP_(—)05083049.1, YP_(—)554098.1, ZP_(—)01900149.1, ADG26619.1, ADG26657.1, ADG26640.1, ZP_(—)06838771.1, ADG26649.1, ADG26651.1, ZP_(—)02374120.1, YP_(—)368326.1, ZP_(—)02380481.1, ADG26643.1, ADG26628.1, YP_(—)442346.1, ADG26620.1, ADG26647.1, ZP_(—)07673680.1, ADG26638.1, YP_(—)002232139.1, YP_(—)001118743.1, ZP_(—)01764629.1, YP_(—)108945.1, YP_(—)334185.1, ZP_(—)04897834.1, ZP_(—)02889567.1, YP_(—)620386.1, YP_(—)002897546.1, ZP_(—)02166109.1, ZP_(—)02904755.1, ADG26639.1, YP_(—)001892637.1, ADG26642.1, ZP_(—)04939380.1, ZP_(—)02464124.1, YP_(—)102417.1, CAC36356.1, ACJ22727.1, YP_(—)001764240.1, YP_(—)002765609.1, YP_(—)001945311.1, ZP_(—)03586616.1, ACJ22665.1, ZP_(—)03574223.1, CAC37038.1, ZP_(—)02456517.1, YP_(—)001807560.1, YP_(—)002779449.1, AAK97454.1, YP_(—)002912304.1, ACR55689.1, YP_(—)003397515.1, YP_(—)004361423.1, YP_(—)772734.1, ACJ65014.1, ACT31523.1, ACJ22750.1, ZP_(—)07375042.1, YP_(—)002776786.1, ACB11552.1, ZP_(—)02363472.1, ADG26653.1, ZP_(—)04383196.1, ZP_(—)02356342.1, ACJ22751.1, YP_(—)952571.1, ACU43494.1, YP_(—)001135977.1, YP_(—)002764193.1, YP_(—)003855036.1, YP_(—)004078475.1, AAK97448.1, ZP_(—)04388098.1, ACX30747.1, ADG26632.1, ACJ22719.1, ADO21492.1, ZP_(—)05061580.1, ADR72654.1, ACZ65961.1, ACX30755.1, YP_(—)001849604.1, AAV64895.1, YP_(—)004495037.1, YP_(—)702497.1, YP_(—)001069662.1, ZP_(—)06850622.1, BAF34299.1, CAB51024.2, YP_(—)004008018.1, YP_(—)003768535.1, ACJ65013.1, ZP_(—)07282765.1, YP_(—)886209.1, ACJ22725.1, ZP_(—)08155372.1, YP_(—)004493362.1, ZP_(—)05228000.1, ZP_(—)07717360.1, BAD67020.1, YP_(—)004524245.1, ZP_(—)07715778.1, NP_(—)217769.1, ACS91349.1, YP_(—)960105.1, ZP_(—)07014137.1, YP_(—)004746682.1, ZP_(—)08022271.1, ACN62569.1, ADQ37951.1, YP_(—)003647687.1, YP_(—)003837040.1, ADG26600.1, YP_(—)002768905.1, ZP_(—)08553310.1, ADG26597.1, ACJ22749.1, ADG26598.1, YP_(—)001704327.1, ZP_(—)04385381.1, ZP_(—)04751264.1, ADG26609.1, ADG26610.1, ZP_(—)06417258.1, ADG26607.1, ADP98338.1, YP_(—)003275257.1, YP_(—)004084103.1, ADG26630.1, ADG26625.1, ADG26605.1, ADG26599.1, ZP_(—)05218167.1, ADQ37950.1, YP_(—)921354.1, ADG26645.1, ADG26612.1, YP_(—)004493370.1, YP_(—)638501.1, YP_(—)003809668.1, NP_(—)962298.1, ZP_(—)04750514.1, ADG26608.1, ADT82701.1, ACJ06773.1, YP_(—)120833.1, ADG26618.1, ADG26602.1, ADG26623.1, ZP_(—)04383566.1, ZP_(—)08122407.1, YP_(—)004077166.1, ZP_(—)05041651.1, ZP_(—)04608296.1, ABU93351.2, YP_(—)003658078.1, ADQ37949.1, ADG26652.1, YP_(—)002765850.1, AAK97447.1, CAD24434.1, CAC40954.1, ACT91203.1, YP_(—)120829.1, ZP_(—)07282558.1, YP_(—)003298195.1, YP_(—)001851790.1, ZP_(—)05827357.1, ADG26633.1, CAB51020.1, YP_(—)953908.1, ZP_(—)07990416.1, YP_(—)119532.1, ZP_(—)08442348.1, ZP_(—)08276444.1, ZP_(—)04661203.1, ABO12068.2, YP_(—)001846325.1, ADQ37952.1, ZP_(—)08198697.1, ZP_(—)00996652.1, YP_(—)001707231.1, ZP_(—)08433663.1, ZP_(—)08205256.1, YP_(—)003732372.1, YP_(—)906529.1, ACT91204.1, YP_(—)001506534.1, YP_(—)001713880.1, YP_(—)883357.1, YP_(—)004525252.1, ADG26604.1, YP_(—)001134633.1, ZP_(—)08195602.1, ZP_(—)06690500.1, ZP_(—)05826167.1, ADY81595.1, ZP_(—)06056754.1, AAK31348.1, YP_(—)251715.1, ZP_(—)08461977.1, ZP_(—)05847237.1, YP_(—)712218.1, YP_(—)001084670.1, ZP_(—)04387164.1, YP_(—)260041.1, YP_(—)002873097.1, ADG26614.1, AAK97446.1, YP_(—)001280943.1, ZP_(—)04386125.1, AAC36353.2, CCA29159.1, CAD10804.1, CCA29151.1, CAC40953.1, CCA29161.1, ABA55770.1, AAS93604.4, CCA29173.1, CCA29155.1, CCA29156.1, ABA55772.1, CCA29154.1, ABA55793.1, CCA29162.1, CCA29170.1, ZP_(—)03824539.1, CCA29166.1, CCA29136.1, ZP_(—)06065934.1, ABB54493.1, CCA29169.1, YP_(—)003112137.1, CCA29127.1, CCA29148.1, CCA29160.1, ZP_(—)06057458.1, ABA55773.1, YP_(—)004016090.1, CCA29139.1, YP_(—)480358.1, ABA55787.1, CCA29150.1, CCA29130.1, ZP_(—)07775830.1, ABA55779.1, CCA29132.1, YP_(—)003732938.1, BAB33284.1, CCA29149.1, CCA29145.1, ABA55783.1, CCA29137.1, CCA29129.1, CCA29158.1, CCA29176.1, CCA29142.1, CCA29144.1, BAB33287.1, CCA29133.1, CCA29140.1, CCA29135.1, ZP_(—)06066074.1, ZP_(—)03823182.1, CCA29171.1, CCA29152.1, CCA29131.1, ABA55780.1, CCA29163.1, CCA29143.1, CCA29153.1, YP_(—)001580600.1, CCA29134.1, CCA29138.1, YP_(—)046098.1, ZP_(—)06072466.1, ZP_(—)05361594.1, ACU43504.1, CCA29147.1, CCA29146.1, ZP_(—)06061712.1, ACT91185.1, ACT91147.1, ACT91178.1, ACT91167.1, ACT91181.1, ACT91188.1, ZP_(—)06069784.1, ACT91205.1, ZP_(—)06725872.1, ACT91171.1, CCA29128.1, ABY56787.1, ADE05602.1, ACU43474.1, ACJ22718.1, ABB90688.1, ACU43519.1, ABB96093.1, ACU43485.1, ACU43493.1, ABW76857.1, ACT91163.1, ACJ22673.1, ZP_(—)06188150.1, ACT91242.1, ACT91225.1, ACT91211.1, ACU43479.1, ACU43491.1, ACU43522.1, ACU43486.1, ACT91221.1, ACJ22662.1, ACU43506.1, ACU43487.1, ACT91259.1, AAA97866.1, ACU43502.1, YP_(—)001252544.1, ABB96084.1, ACU43520.1, ACJ22668.1, ACU43503.1, ACT91230.1, ABA55777.1, ACT91231.1, ZP_(—)01748311.1, ACJ22724.1, ACU43475.1, ACU43511.1, ACU43490.1, ZP_(—)08330953.1, ACU43484.1, CBX01596.1, ACT91168.1, YP_(—)096989.1, ACT91215.1, YP_(—)125370.1, ACT91233.1, ACU43478.1, ADE05603.1, ACJ22715.1, ACU43512.1, ACT91196.1, ACJ22692.1, ACU43510.1, ACU43521.1, ACT91174.1, ACT91213.1, ACT91142.1, ACT91206.1, ACT91216.1, ACT91182.1, ACT91255.1, ACT91246.1, ACT91217.1, ACT91155.1, ACT91240.1, ACT91207.1, ACU43495.1, YP_(—)128249.1, ACT91160.1, YP_(—)004052990.1, ACT91226.1, ACU43507.1, ABO61855.1, ACT91214.1, ACT91220.1, YP_(—)001188237.1, ACJ22689.1, ZP_(—)01689499.1, YP_(—)004379711.1, ACJ22748.1, ABB90683.1, ACT91223.1, ACT91235.1, ABO61786.1, ACU43508.1, ACU43492.1, ACT91219.1, ACT91244.1, ABO61856.1, ACT91239.1, ACU43473.1, ABO61850.1, ACT91262.1, ACT91261.1, ACT91224.1, ACU43499.1, ACU43488.1, ADO21767.1, YP_(—)004654946.1, ADO21777.1, ABB96089.1, ABO61852.1, ABO61847.1, ACT91222.1, ADO21764.1, ACU43477.1, ADO21773.1, ABO61787.1, ABB96080.1, ABO61857.1, ACT91228.1, ABB96070.1, ADO21744.1, ACT91245.1, CAG17608.1, ADO21747.1, YP_(—)001349162.1, ABK63807.1, ZP_(—)06879583.1, NP_(—)250216.1, ACT91234.1, ZP_(—)01364874.1, ABO61789.1, ADO21772.1, ACU43516.1, ACU43505.1, ACU43501.1, ACT91236.1, ZP_(—)07792758.1, ACZ64723.1, ADO21743.1, ADO21759.1, ACZ64752.1, ADO21755.1, ACD75517.1, YP_(—)790621.1, ACB11551.1, ADO21748.1, NP_(—)251264.1, ZP_(—)01365940.1, ADO21762.1, ADO21739.1, ACU43496.1, ABO61854.1, ZP_(—)06878434.1, ACU43489.1, ACU43483.1, ADO21746.1, ACT91237.1, ZP_(—)01895378.1, ACT91164.1, ADO21736.1, ACJ22711.1, ACZ64754.1, ZP_(—)05042146.1, ADO21688.1, ADO21648.1, YP_(—)001348003.1, ADP98656.1, ADO21737.1, ADO21760.1, ADO21754.1, ADO21740.1, ACZ64758.1, ACU43497.1, ZP_(—)01912185.1, ABB96111.1, ACU43482.1, ACB11549.1, ADO21775.1, CCA29157.1, ADO21681.1, ADO21668.1, ADO21656.1, ACU43517.1, ACT91165.1, ACJ22695.1, ACJ22688.1, ABB96071.1, ADO21763.1, ACT91241.1, ADO21735.1, ACB11550.1, ADO21778.1, ACT91172.1, ADO21765.1, ABB96087.1, CBJ30233.1, ACJ22752.1, ABB96105.1, ACB15251.1, ACJ22694.1, ACZ64741.1, ACZ64706.1, ABB96108.1, ACT91191.1, ABB96101.1, ABB90691.1, ACZ64745.1, YP_(—)691842.1, ABB96075.1, ABB90682.1, ABB90690.1, ADO21676.1, ADO21679.1, ABO61768.1, YP_(—)435857.1, ACJ22722.1, ACT91238.1, ACZ64725.1, CAC14062.1, ADO21682.1, ACZ64771.1, ACZ64718.1, ACZ64724.1, ADO21670.1, ADO21667.1, CAC37048.1, ACZ64708.1, ABB96092.1, ACJ22687.1, ACZ64703.1, ADO21690.1, ABB92364.1, ACB11547.1, ACZ64720.1, ADO21655.1, ACZ64717.1, ADO21680.1, ACZ64757.1, ACZ64733.1, ACT91144.1, ACU43481.1, ACT91179.1, ZP_(—)02181409.1, ACZ64704.1, ABB96073.1, ACJ22675.1, ACZ64721.1, ABB96090.1, ACJ22729.1, ACU43515.1, ZP_(—)01307000.1, ABB90685.1, YP_(—)003862088.1, ACZ64715.1, ACZ64710.1, ACJ22735.1, ABB90687.1, ADO21661.1, ADO21674.1, ACT91177.1, ABB54492.1, ABB96076.1, ABB92365.1, ACT91194.1, ADO21689.1, ACJ22691.1, ABB90681.1, ADO21649.1, ADO21671.1, ACZ64728.1, ABB96095.1, CAC40945.1, ADO21652.1, ADO21665.1, ADE08461.1, ADO21678.1, ACZ64705.1, ACJ22690.1, ADO21675.1, ADO21685.1, ABB96072.1, ACJ22736.1, ACB11540.1, ABB96091.1, ACI04540.1, ACT91251.1, ACT91146.1, ACT91166.1, ACT91156.1, ADO21752.1, ADO21673.1, ADO21725.1, ABB96104.1, ABB90694.1, ABB90696.1, ACT91173.1, ADO21647.1, ZP_(—)03700804.1, ACT91232.1, ADO21694.1, CAC40949.1, ABB92361.1, ACT91195.1, ACI04538.1, ADO21691.1, ACJ22685.1, ADO21653.1, ABS12461.1, ACZ64736.1, ACZ64772.1, ABB90680.1, ADO21659.1, ACZ64774.1, ADO21684.1, ADO21729.1, ADO21650.1, ADO21733.1, ACZ64755.1, ACZ64751.1, ABA55775.1, ADO21738.1, CCA29174.1, ADO21669.1, ACZ64744.1, ADO21654.1, ADO21768.1, ABB96106.1, CCA29168.1, ACT91176.1, ACB11555.1, ABB90695.1, ADO21660.1, ACJ22666.1, ACZ64778.1, ADO21766.1, ADO21677.1, ZP_(—)02161687.1, CCA29165.1, ADO21745.1, ACB11548.1, ABB90689.1, ABB96107.1, AAT46052.1, ADO21718.1, ADO21722.1, ABB96088.1, EFW40271.1, ADO21686.1, ABB96103.1, ACU43500.1, ACB11536.1, ABB92360.1, CCA29167.1, ACT91199.1, ACZ64770.1, ACJ22716.1, ABA55786.1, ACZ64737.1, ABB96083.1, ACJ22676.1, ACZ64735.1, ACT91212.1, ACJ22765.1, CAJ01371.1, CAC17734.1, ABD36389.1, ACB11537.1, CAC08515.1, ACZ64714.1, ACU43513.1, ABB96082.1, ADN21387.1, ADO21711.1, ABD36392.1, ABR10770.1, CAC37049.1, ABB96098.1, ABB90692.1, ACB11535.1, ACZ64768.1, ACJ22756.1, ABB96094.1, ABA55791.1, ABB96078.1, ACT91141.1, ACZ64779.1, ACZ64750.1, CAJ01370.1, ACZ64753.1, ACU43480.1, ABA55794.1, ABB96085.1, ABB96110.1, YP_(—)004448035.1, ACZ64709.1, ABB96102.1, ACZ64773.1, CCA29175.1, ACZ64749.1, ACZ64756.1, ACZ64781.1, ABO61777.1, ACZ64759.1, ACZ64764.1, ACZ64740.1, ACT91249.1, ZP_(—)03702922.1, ACB11545.1, ACZ64775.1, ACZ64769.1, ACT91145.1, ACZ64742.1, ACT91254.1, ACZ64762.1, ACZ64716.1, ACZ64777.1, ADM26559.1, ABB96096.1, ACZ64780.1, ZP_(—)01201250.1, CAH55829.1, ZP_(—)01052921.1, ABB96077.1, ADO21658.1, ACT91161.1, ABB90684.1, ACR56750.1, ABB90697.1, ACZ64746.1, ABB92367.1, ACT91139.1, ACZ64763.1, ACT91200.1, ABO61773.1, ABB96081.1, ACZ64748.1, ACZ64782.1, ACU43498.1, ADO21651.1, ABB90679.1, BAG06233.1, ACZ64747.1, ABB96086.1, ACZ64761.1, ABB92370.1, ABO61774.1, ACT91175.1, ABB90686.1, ACB11546.1, ZP_(—)01740604.1, ABO61785.1, YP_(—)001531377.1, XP_(—)001434539.1, ABA55767.1, ABO21865.1, ABF55636.1, ABA55751.1, ABB90698.1, ADD12311.1, ACZ64765.1, ABB92366.1, ABB92368.1, ACI04539.1, XP_(—)001023288.1, ACZ64783.1, ADO21692.1, ZP_(—)01753800.1, ACZ64760.1, ACZ64700.1, ZP_(—)01055480.1, ACZ64767.1, ACZ64701.1, ABA55745.1, ABA55752.1, ACZ64766.1, YP_(—)614640.1, ABA55759.1, ADO21723.1, BAG06232.1, ZP_(—)01002389.1, ABB90693.1, ACT91264.1, ABB92358.1, BAF99026.1, ABR10769.1, ZP_(—)00959618.1, AEA08580.1, ADD22986.1, CAB51023.1, CAC40958.1, ADO21709.1, CAB51025.1, ACI15226.1, ACJ22680.1, ZP_(—)05741459.1, ACT91248.1, ABU48567.1, ABO61792.1, ACJ22754.1, EFN53276.1, AAL87644.1, ACT91209.1, ZP_(—)02147281.1, ACU43518.1, ACZ64776.1, ACB11543.1, ACT91151.1, ACJ22764.1, ACT91159.1, ABA18186.1, AEA08579.1, ADO21770.1, ABF55634.1, CAA27179.1, ABA55741.1, ADO21705.1, ZP_(—)01754375.1, ACB11541.1, ACR56751.1, ACT91250.1, ADO21769.1, ADO21753.1, ABB96097.1, ACT91208.1, ABO21867.1, ADO21757.1, ACB11554.1, ABA55749.1, CAC40951.1, ADO21719.1, ABB96074.1, ZP_(—)00954267.1, ZP_(—)05786269.1, AEH76912.1, ABA55742.1, ABA55748.1, BAG06236.1, ADO21732.1, ABA55750.1, ABA55768.1, ACT31522.1, ZP_(—)05090796.1, ACZ64739.1, YP_(—)915886.1, ADO21731.1, CAC40948.1, XP_(—)001032273.1, AEH76911.1, ABA55743.1, ABO61769.1, ABA55755.1, ZP_(—)05122263.1, ADO21756.1, ABA55744.1, ABA55746.1, ZP_(—)01901011.1, ZP_(—)02150761.1, ADO21742.1, ACR56752.1, ABA55747.1, ABF55637.1, ABA55740.1, ABA55760.1, ZP_(—)00948812.1, ABA55804.1, ADO21771.1, ZP_(—)05342453.1, ABF55638.1, YP_(—)508336.1, ABB92357.1, ZP_(—)01049702.1, ABU48546.1, ABU48555.1, ABA55764.1, ABO21866.1, ZP_(—)05079274.1, ZP_(—)01880441.1, ACZ64738.1, ZP_(—)05842058.1, ACT91218.1, ABA55769.1, ABA55739.1, ABA55803.1, ACT91247.1, ABA55782.1, ACZ17539.1, ABB92359.1, ACH69966.1, ZP_(—)01035050.1, ACZ17537.1, ABA55774.1, ACZ64729.1, ACZ17538.1, ZP_(—)01751972.1, ACZ64731.1, ACZ64702.1, AAR13803.1, AEJ28400.1, ZP_(—)05099213.1, CAB51021.1, ACZ17531.1, AEH76914.1, ZP_(—)05051648.1, ACZ64726.1, ACZ17540.1, ACZ64727.1, ZP_(—)02152773.1, ACT91253.1, ACZ17536.1, XP_(—)001423873.1, ACZ17534.1, YP_(—)168645.1, ACZ17520.1, ABY56786.1, ACB11539.1, ZP_(—)01157350.1, AEH76910.1, ABY56784.1, AAY85982.1, ACT91257.1, ACB11544.1, ACZ17532.1, ZP_(—)01746661.1, ABA55771.1, BAG06235.1, EGR32049.1, YP_(—)001166282.1, ABO61799.1, ABA55757.1, AEH76915.1, ACO59264.1, ABO26125.1, AEA08577.1, ACT91265.1, ABY56785.1, ACZ17528.1, ABO61798.1, ADO21749.1, ACT91263.1, ACT91252.1, ACZ64722.1, ABO61771.1, ACZ17526.1, ABO26123.1, ADO21714.1, ZP_(—)01000906.1, ABO61796.1, ADC29534.1, ACB15250.1, ACD47155.1, ACZ17525.1, ACB11553.1, ABD36391.1, AEH76913.1, ACZ17523.1, ABO61781.1, ACZ17524.1, ZP_(—)01914093.1, ACB11538.1, ZP_(—)01015838.1, ACJ22693.1, ACB15252.1, CAC86945.1, ACO59265.1, ABO61791.1, ACZ17521.1, ABO26124.1, ACZ64732.1, ACU43514.1, ACT91256.1, ACM63043.1, ACS75820.1, ZP_(—)08666479.1, CAH03133.1, BAG06234.1, AEH76916.1, ABO61790.1, ABE72965.1, ACZ64711.1, ACB11542.1, AAY26148.1, ABA55776.1, ACZ17522.1, ACZ64734.1, AEA08578.1, ACZ17530.1, ZP_(—)04062748.1, ACJ22755.1, NP_(—)969039.1, AAY26149.1, ACJ22761.1, ABU48543.1, ZP_(—)08414255.1, AAT91720.1, ZP_(—)01444283.1, ABA55796.1, ABU48542.1, YP_(—)001042010.1, YP_(—)001234392.1, YP_(—)351510.1, ACZ64730.1, ZP_(—)08634611.1, ACZ17529.1, ACJ22667.1, AAT91719.1, YP_(—)004283531.1, ABO61801.1, ACZ17519.1, ABO15266.1, CAB51040.1, ACZ64707.1, ACJ22766.1, ABO26121.1, ZP_(—)01878984.1, CAB51039.1, ABA55795.1, ABO15269.1, ABO15247.1, ACJ22763.1, ABO15251.1, ACZ17527.1, ABO15270.1, ACJ22769.1, ADE06670.1, ZP_(—)05780387.1, ABO61770.1, ACT91258.1, ABO15258.1, ABO15257.1, ABU48545.1, CAC86946.1, ABO15267.1, ZP_(—)01741446.1, ABU48544.1, YP_(—)002296646.1, AEH76917.1, ADC29550.1, YP_(—)002527219.1, ABK88246.1, ADN21388.1, ACT91210.1, ZP_(—)05064795.1, ABJ16487.1, XP_(—)002675644.1, ABJ16489.1, ADA71089.1, ADA71088.1, AAT46053.1, ZP_(—)01744806.1, ZP_(—)01037964.1, ZP_(—)00955262.1, ABJ16493.1, YP_(—)001840157.1, ZP_(—)00964204.1, ABB40596.1, ACB15249.1, ADD82963.1, YP_(—)004499590.1, ZP_(—)01011524.1, ACJ22758.1, ZP_(—)01748906.1, ACV30052.1, ZP_(—)06191942.1, YP_(—)001188029.1, ACD63080.1, YP_(—)166583.1, AAV41375.1, ZP_(—)00998265.1, ACJ22757.1, ABB13506.2, ABI13999.1, ABI14004.1, ABB13509.1, YP_(—)371980.1, ZP_(—)01755711.1, ZP_(—)05065835.1, ZP_(—)00959368.1, XP_(—)001020063.1, ABJ16481.1, ABI14006.1, ZP_(—)05101918.1, ZP_(—)01913733.1, ABI14001.1, ABM92270.1, ABI14003.1, CAH03132.1, YP_(—)973211.1, ABA55797.1, YP_(—)003578527.1, ABJ16483.1, ABJ16482.1, CBY78068.1, ACT91260.1, YP_(—)509155.1, ABB13508.1, ABJ16485.1, ABO61779.1, ABI14005.1, ACM63042.1, ADC29543.1, ZP_(—)02153440.1, YP_(—)709335.1, ABI13998.1, ABI14002.1, AAB70825.1, ACX30751.1, ABI14000.1, YP_(—)003617173.1, ZP_(—)01155421.1, ACX30752.1, NP_(—)542887.1, ADC29546.1, AAC38359.1, ADC29541.1, XP_(—)001020064.1, ZP_(—)01442436.1, ZP_(—)05103090.1, ADC29544.1, ABO61809.1, AAY89939.1, ACH99235.1, CAH55830.1, ABO26095.1, YP_(—)004011670.1, ABO26084.1, ADA71083.1, ABO26087.1, ABO61806.1, ADC29531.1, ABO26109.1, ACJ22753.1, ABO26089.1, ABO26093.1, ABO26092.1, ABO61827.1, ABO26105.1, ABO26112.1, AAT91721.1, ABO26120.1, ABO26090.1, ABO26088.1, ABO61811.1, ABO61783.1, CAH55827.1, ACH99232.1, ABO61828.1, ADC29530.1, ACH99234.1, AAQ88276.1, CAH55823.1, ABO26103.1, ACH99233.1, ABO61836.1, ABO26094.1, ABO61840.1, YP_(—)004534277.1, ZP_(—)05845010.1, ABO61821.1, ACH99231.1, AAV68403.1, ABO61839.1, CAH56098.1, ABO26085.1, ABO61826.1, ABO61822.1, ABO26110.1, ABO61810.1, ABO61844.1, ABO61825.1, ABO26099.1, ACJ22767.1, ABO26102.1, YP_(—)004535707.1, ACJ22762.1, ABO26097.1, BAC65444.1, ABO61829.1, YP_(—)114083.1, CAH55828.1, ABO26106.1, YP_(—)552229.1, NP_(—)049190.1, ABO26116.1, CAH56107.1, CAM32407.1, ABO26101.1, ABO61841.1, ABM79805.1, ZP_(—)05075249.1, AAC27438.2, YP_(—)003754872.1, ADC29532.1, ADA71139.1, ADA71107.1, ADA71095.1, YP_(—)001268217.1, ADA71126.1, ADA71094.1, CAH56108.1, ADC29533.1, ADA71085.1, ZP_(—)05054453.1, ADA71097.1, ADA71086.1, ADA71114.1, ADC29548.1, ADA71101.1, ADC29547.1, ADA71138.1, ADC29542.1, ADA71098.1, ADA71128.1, ADA71105.1, ADA71093.1, ADA71135.1, ADA71100.1, YP_(—)557479.1, ADA71113.1, ADA71091.1, ADC29537.1, ADA71084.1, ADA71090.1, CAH56094.1, XP_(—)002945767.1, ADA71137.1, ADA71103.1, ADA71118.1, ADA71133.1, ADA71102.1, ADC29536.1, CAH56100.1, CAH56101.1, ACI15225.1, ACI15225.1, ABO26091.1, CAH55826.1, CAH55824.1, ZP_(—)08484419.1, ADA71111.1, ACJ22759.1, CAH55825.1, CAH56106.1, CAH56099.1, CAC40957.1, ZP_(—)05075037.1, CAH56102.1, ZP_(—)06846296.1, ABJ16491.1, ZP_(—)05067177.1, XP_(—)001698107.1, BAH10789.1, BAH10791.1, BAH10793.1, BAH10788.1, ABJ16490.1, BAH10800.1, BAH10790.1, BAH10792.1, ZP_(—)05075214.1, BAH10799.1, BAH10795.1, BAH10787.1, BAH10798.1, BAH10794.1, BAH10801.1, BAH10796.1, BAH10797.1, BAH10802.1, CAH56095.1, CAH56096.1, ADC29538.1, ABX76425.1, ZP_(—)06727686.1, ZP_(—)07774883.1, YP_(—)001615042.1, in particular YP_(—)001185946.1, Q9WWW6.1, YP_(—)957898.1, YP_(—)957728.1, YP_(—)694427.1, BAC98365.1, ZP_(—)00957064.1, CAC86944.1, YP_(—)001672212.1, CAB59525.1, ACH99213.1, ACH99215.1, ACH99216.1, AAK56792.1, ACH99229.1, ACS91348.1, AAP41820.1 and particularly preferably YP_(—)001185946.1, and proteins with a polypeptide sequence wherein up to 60%, preferably up to 25%, particularly preferably up to 15%, in particular up to 10, 9, 8, 7, 6, 5, 4, 3, 2 or 1% of the amino acid residues are modified compared to the aforementioned reference sequences by deletion, insertion, substitution or a combination thereof and which still possess at least 50%, preferably 65%, particularly preferably 80%, in particular more than 90% of the activity of the protein with the corresponding, aforementioned reference sequence, wherein 100% activity of the reference protein is understood to mean the increasing of the activity of the cells used as a biocatalyst, i.e. the quantity of substance converted per unit time based on the cell quantity used (units per gram cell dry weight [U/g CDW]) in comparison to the activity of the biocatalyst in the absence of the reference protein, wherein the activity in this connection and in connection with the determination of the activity of the enzyme E_(1b) in general is understood to mean in particular the conversion of lauric acid and/or methyl laurate to ω-hydroxylauric acid and/or methyl ω-hydroxylaurate.

Auxiliary Enzymes to E₁

It is preferable according to the invention that, if E_(1a) is a eukaryotic P450 alkane hydroxylase, the microorganism according to the invention also has increased activity of a NADPH cytochrome P450 oxidoreductase of EC 1.6.2.4 in comparison to its wild type. This has the technical effect that the activity of the eukaryotic P450 alkane hydroxylases is increased and the product yields increased.

NADPH cytochrome P450 oxidoreductases of EC 1.6.2.4 catalyse the following reaction: oxidized cytochrome P450+NADPH⁺=reduced cytochrome P450+NADP⁺+H⁺

It is preferable according to the invention that, if E_(1a) is a prokaryotic P450 alkane hydroxylase of the CYP_(—)153 type, the microorganism according to the invention also has increased activity of a ferredoxin NAD(P)⁺ reductase of EC 1.18.1.2 or EC 1.18.1.3 and/or of a ferredoxin, in comparison to its wild type. This has the technical effect that the activity of the prokaryotic P450 alkane hydroxylase of the CYP_(—)153 type is increased and the product yields increased. Ferredoxin NAD(P)⁺ reductases of EC 1.18.1.2 or EC 1.18.1.3 catalyse the following reaction: oxidized ferredoxin+NAD(P)H+ H⁺=reduced ferredoxin+NAD(P)⁺ and are preferably encoded by a gene which is situated in direct proximity to a gene of an aforementioned prokaryotic P450 alkane hydroxylase of the CYP_(—)153 type or of a ferredoxin described in connection with this invention.

The term “in direct proximity” means that a maximum of three other structural genes are located between the genes in question.

Ferredoxins catalyse the following reactions:

alkane hydroxylase+reduced ferredoxin+alkanoic acid (ester)=alkane monooxygenase+oxidized ferredoxin+ω-hydroxyalkanoic acid (ester)+H₂O, alkane hydroxylase+2 reduced ferredoxins+alkanoic acid (ester)=alkane hydroxylase+2 oxidized ferredoxins+ω-oxoalkanoic acid (ester)+2H₂O or alkane hydroxylase+3 reduced ferredoxins+alkanoic acid (ester)=alkane hydroxylase+3 oxidized ferredoxins+ω-carboxyalkanoic acid (ester)+3H₂O and are preferably encoded by a gene which is situated in direct proximity to a gene of an aforementioned prokaryotic P450 alkane hydroxylase of the CYP_(—)153 type or an aforementioned ferredoxin NAD(P)⁺ reductase of EC 1.18.1.2 or EC 1.18.1.3. The term “in direct proximity” means that a maximum of three other structural genes are located between the genes in question.

Preferred microorganisms display increased activity of the ferredoxin NAD(P)⁺ reductase AlkT and of a ferredoxin in comparison to its wild type.

It is preferable according to the invention that, if E₁ is an AlkB alkane hydroxylase of

EC 1.14.15.3, the microorganism according to the invention also displays increased activity of an AlkT rubredoxin NAD(P)⁺ reductase of EC 1.18.1.1 or of EC 1.18.1.4 and/or of a rubredoxin AlkG in comparison to its wild type. This has the technical effect that the activity of the AlkB alkane hydroxylase is raised and the product yields increased. AlkT rubredoxin NAD(P)⁺ reductases of EC 1.18.1.1 or EC 1.18.1.4 catalyse the following reaction: oxidized rubredoxin+NAD(P)H+H⁺=reduced rubredoxin+NAD(P)⁺ and are preferably encoded by a gene which is situated in direct proximity to a gene of an aforementioned AlkB alkane hydroxylase of EC 1.14.15.3 or of a rubredoxin AlkG described in connection with this invention.

The term “in direct proximity” means that a maximum of three other structural genes are located between the genes in question.

Rubredoxins AlkG catalyse the following reactions:

alkane monooxygenase+reduced rubredoxin+alkanoic acid (ester)=alkane monooxygenase+oxidized rubredoxin+ω-hydroxyalkanoic acid (ester)+H₂O, alkane monooxygenase+2 reduced rubredoxins+alkanoic acid (ester)=alkane monooxygenase+2 oxidized rubredoxins+ω-oxoalkanoic acid (ester)+2H₂O or alkane monooxygenase+3 reduced rubredoxins+alkanoic acid (ester)=alkane monooxygenase+3 oxidized rubredoxins+ω-carboxyalkanoic acid (ester)+3H₂O and are preferably encoded by a gene which is situated in direct proximity to a gene of an aforementioned AlkB alkane hydroxylase of EC 1.14.15.3 or an aforementioned AlkT rubredoxin NAD(P)⁺ reductase of EC 1.18.1.1 or EC 1.18.1.4. The term “in direct proximity” means that a maximum of three other structural genes are located between the genes in question.

Preferred microorganisms display increased activity of the AlkT rubredoxin NAD(P)⁺ reductase and of the rubredoxin AlkG in comparison to its wild type.

Enzyme E₂ ω-Amination

It is preferable according to the invention to provide a microorganism which in particular is capable of producing ω-functionalized carboxylic acids and ω-functionalized carboxylate esters from at least one simple carbon source, where the ω-functionalization corresponds to an amino group, in particular primary, in the ω position. Thereby, the microorganisms can advantageously be used in processes for the production of ω-aminocarboxylic acids or ω-aminocarboxylate esters.

Hence microorganisms preferred according to the invention are characterized in that the second genetic modification additionally comprises that the microorganism displays increased activity of an enzyme E₂, which catalyses the conversion of ω-oxocarboxylic acids or ω-oxocarboxylate esters to the corresponding ω-aminocarboxylic acids or ω-aminocarboxylate esters, in comparison to its wild type.

According to the invention, the enzyme E₂ is preferably an ω-transaminase of EC 2.6.1.-.

As a measure of the enzyme activity E₂, the conversion of ω-oxolauric acid and/or methyl ω-oxolaurate to ω-aminolauric acid and/or methyl ω-aminolaurate can in particular be utilized.

Preferred enzymes E₂ are selected from the group:

3HMU_A, AAD41041.1, AAK15486.1, ABE03917.1, ADR60699.1, ADR61066.1, ADR62525.1, AEL07495.1, CAZ86955.1, EFW82310.1, EFW87681.1, EGC99983.1, EGD03176.1, EGE58369.1, EGH06681.1, EGH08331.1, EGH24301.1, EGH32343.1, EGH46412.1, EGH55033.1, EGH62152.1, EGH67339.1, EGH70821.1, EGH71404.1, EGH78772.1, EGH85312.1, EGH97105.1, EGP57596.1, NP_(—)102850.1, NP_(—)106560.1, NP_(—)248912.1, NP_(—)248990.1, NP_(—)354026.2, NP_(—)421926.1, NP_(—)637699.1, NP_(—)642792.1, NP_(—)744329.1, NP_(—)744732.1, NP_(—)747283.1, NP_(—)795039.1, NP_(—)901695.1 (encoded by SEQ ID No. 12), XP_(—)002943905.1, YP_(—)001021095.1, YP_(—)001059677.1, YP_(—)001061726.1, YP_(—)001066961.1, YP_(—)001074671.1, YP_(—)001120907.1, YP_(—)001140117.1, YP_(—)001170616.1, YP_(—)001185848.1, YP_(—)001188121.1, YP_(—)001233688.1, YP_(—)001268866.1, YP_(—)001270391.1, YP_(—)001345703.1, YP_(—)001412573.1, YP_(—)001417624.1, YP_(—)001526058.1, YP_(—)001579295.1, YP_(—)001581170.1, YP_(—)001668026.1, YP_(—)001669478.1, YP_(—)001671460.1, YP_(—)001685569.1, YP_(—)001747156.1, YP_(—)001749732.1, YP_(—)001765463.1, YP_(—)001766294.1, YP_(—)001790770.1, YP_(—)001808775.1, YP_(—)001809596.1, YP_(—)001859758.1, YP_(—)001888405.1, YP_(—)001903233.1, YP_(—)001977571.1, YP_(—)002229759.1, YP_(—)002231363.1, YP_(—)002280472.1, YP_(—)002297678.1, YP_(—)002543874.1, YP_(—)002549011.1, YP_(—)002796201.1, YP_(—)002801960.1, YP_(—)002875335.1, YP_(—)002897523.1, YP_(—)002912290.1, YP_(—)002974935.1, YP_(—)003060891.1, YP_(—)003264235.1, YP_(—)003552364.1, YP_(—)003578319.1, YP_(—)003591946.1, YP_(—)003607814.1, YP_(—)003641922.1, YP_(—)003674025.1, YP_(—)003692877.1, YP_(—)003755112.1, YP_(—)003896973.1, YP_(—)003907026.1, YP_(—)003912421.1, YP_(—)004086766.1, YP_(—)004142571.1, YP_(—)004147141.1, YP_(—)004228105.1, YP_(—)004278247.1, YP_(—)004305252.1, YP_(—)004356916.1, YP_(—)004361407.1, YP_(—)004378186.1, YP_(—)004379856.1, YP_(—)004390782.1, YP_(—)004472442.1, YP_(—)004590892.1, YP_(—)004612414.1, YP_(—)004676537.1, YP_(—)004693233.1, YP_(—)004701580.1, YP_(—)004701637.1, YP_(—)004704442.1, YP_(—)108931.1, YP_(—)110490.1, YP_(—)168667.1, YP_(—)237931.1, YP_(—)260624.1, YP_(—)262985.1, YP_(—)271307.1, YP_(—)276987.1, YP_(—)334171.1, YP_(—)337172.1, YP_(—)350660.1, YP_(—)351134.1, YP_(—)364386.1, YP_(—)366340.1, YP_(—)369710.1, YP_(—)370582.1, YP_(—)426342.1, YP_(—)440141.1, YP_(—)442361.1, YP_(—)468848.1, YP_(—)521636.1, YP_(—)554363.1, YP_(—)608454.1, YP_(—)610700.1, YP_(—)614980.1, YP_(—)622254.1, YP_(—)625753.1, YP_(—)680590.1, YP_(—)751687.1, YP_(—)767071.1, YP_(—)774090.1, YP_(—)774932.1, YP_(—)788372.1, YP_(—)858562.1, YP_(—)928515.1, YP_(—)983084.1, YP_(—)995622.1, ZP_(—)00948889.1, ZP_(—)00954344.1, ZP_(—)00959736.1, ZP_(—)00998881.1, ZP_(—)01011725.1, ZP_(—)01037109.1, ZP_(—)01058030.1, ZP_(—)01076707.1, ZP_(—)01103959.1, ZP_(—)01167926.1, ZP_(—)01224713.1, ZP_(—)01442907.1, ZP_(—)01446892.1, ZP_(—)01550953.1, ZP_(—)01625518.1, ZP_(—)01745731.1, ZP_(—)01750280.1, ZP_(—)01754305.1, ZP_(—)01763880.1, ZP_(—)01769626.1, ZP_(—)01865961.1, ZP_(—)01881393.1, ZP_(—)01901558.1, ZP_(—)02145337.1, ZP_(—)02151268.1, ZP_(—)02152332.1, ZP_(—)02167267.1, ZP_(—)02190082.1, ZP_(—)02242934.1, ZP_(—)02360937.1, ZP_(—)02367056.1, ZP_(—)02385477.1, ZP_(—)02456487.1, ZP_(—)02883670.1, ZP_(—)03263915.1, ZP_(—)03263990.1, ZP_(—)03400081.1, ZP_(—)03452573.1, ZP_(—)03456092.1, ZP_(—)03517291.1, ZP_(—)03529055.1, ZP_(—)03571515.1, ZP_(—)03572809.1, ZP_(—)03587785.1, ZP_(—)03588560.1, ZP_(—)03697266.1, ZP_(—)03697962.1, ZP_(—)04521092.1, ZP_(—)04590693.1, ZP_(—)04890914.1, ZP_(—)04891982.1, ZP_(—)04893793.1, ZP_(—)04902131.1, ZP_(—)04905327.1, ZP_(—)04941068.1, ZP_(—)04944536.1, ZP_(—)04945255.1, ZP_(—)04959332.1, ZP_(—)04964181.1, ZP_(—)05053721.1, ZP_(—)05063588.1, ZP_(—)05073059.1, ZP_(—)05077806.1, ZP_(—)05082750.1, ZP_(—)05091128.1, ZP_(—)05095488.1, ZP_(—)05101701.1, ZP_(—)05116783.1, ZP_(—)05121836.1, ZP_(—)05127756.1, ZP_(—)05637806.1, ZP_(—)05742087.1, ZP_(—)05783548.1, ZP_(—)05786246.1, ZP_(—)05843149.1, ZP_(—)05945960.1, ZP_(—)06459045.1, ZP_(—)06487195.1, ZP_(—)06492453.1, ZP_(—)06493162.1, ZP_(—)06703644.1, ZP_(—)06731146.1, ZP_(—)06839371.1, ZP_(—)07007312.1, ZP_(—)07266194.1, ZP_(—)07374050.1, ZP_(—)07662787.1, ZP_(—)07778196.1, ZP_(—)07797983.1, ZP_(—)08099459.1, ZP_(—)08138203.1, ZP_(—)08141719.1, ZP_(—)08142973.1, ZP_(—)08177102.1, ZP_(—)08185821.1, ZP_(—)08186468.1, ZP_(—)08208888.1, ZP_(—)08266590.1, ZP_(—)08402041.1, ZP_(—)08406891.1, ZP_(—)08522175.1, ZP_(—)08527488.1, ZP_(—)08631252.1, ZP_(—)08636687.1, SEQ ID No. 08, SEQ ID No. 09 in particular NP_(—)901695.1 (encoded by SEQ ID No. 12), ZP_(—)03697266.1, AAD41041.1, YP_(—)002796201.1, ZP_(—)03697962.1, YP_(—)001859758.1, YP_(—)002229759.1, YP_(—)001120907.1, YP_(—)110490.1, ZP_(—)04964181.1, YP_(—)774932.1, YP_(—)001766294.1, YP_(—)001581170.1, YP_(—)622254.1, ZP_(—)03588560.1, YP_(—)001809596.1, YP_(—)370582.1, ZP_(—)03572809.1, NP_(—)248990.1, YP_(—)001888405.1, ZP_(—)04905327.1, YP_(—)001061726.1, YP_(—)001668026.1, ZP_(—)01750280.1, ZP_(—)07778196.1, EGH71404.1, NP_(—)744329.1, YP_(—)004147141.1, ADR61066.1, ZP_(—)05783548.1, YP_(—)004701637.1, YP_(—)366340.1, YP_(—)003264235.1, EGD03176.1, YP_(—)001268866.1, ZP_(—)01901558.1, ZP_(—)05121836.1, YP_(—)003692877.1, ZP_(—)03517291.1, YP_(—)002974935.1, YP_(—)001668026.1, ADR61066.1, NP_(—)744329.1, YP_(—)001268866.1, YP_(—)004701637.1, ZP_(—)08142973.1, ADR62525.1, YP_(—)610700.1, NP_(—)747283.1, ADR62525.1, YP_(—)001270391.1, YP_(—)004704442.1, YP_(—)610700.1, YP_(—)001747156.1, ZP_(—)08138203.1, ZP_(—)07266194.1, EGH70821.1, YP_(—)351134.1, EGH32343.1, EGH08331.1, EGH67339.1, YP_(—)001668026.1, YP_(—)004701637.1, YP_(—)237931.1, ZP_(—)03400081.1, ZP_(—)05116783.1, ZP_(—)01550953.1, ZP_(—)07662787.1, YP_(—)928515.1, YP_(—)788372.1, YP_(—)001021095.1, ZP_(—)07797983.1, YP_(—)003578319.1, YP_(—)004305252.1, NP_(—)248912.1, ZP_(—)08636687.1, YP_(—)003912421.1, YP_(—)751687.1, ZP_(—)08142973.1, YP_(—)271307.1, ZP_(—)05082750.1, YP_(—)001417624.1, YP_(—)353455.1, SEQ ID No. 08, SEQ ID No. 09 and particularly preferably NP_(—)901695.1 (encoded by SEQ ID No. 12), YP_(—)353455.1, SEQ ID No. 08 and SEQ ID No. 09 and proteins with a polypeptide sequence wherein up to 60%, preferably up to 25%, particularly preferably up to 15%, in particular up to 10, 9, 8, 7, 6, 5, 4, 3, 2 or 1% of the amino acid residues compared to the aforementioned reference sequences are modified by deletion, insertion, substitution or a combination thereof and which still possess at least 50%, preferably 65%, particularly preferably 80%, in particular more than 90% of the activity of the protein with the corresponding, aforementioned reference sequence, wherein 100% activity of the reference protein is understood to mean the increasing of the activity of the cells used as a biocatalyst, i.e. the quantity of substance converted per unit time based on the cell quantity used (units per gram cell dry weight [U/g CDW]) in comparison to the activity of the biocatalyst in the absence of the reference protein, wherein the activity in this connection and in connection with the determination of the activity of the enzyme E₂ in general is understood to mean in particular the conversion of ω-oxolauric acid and/or methyl ω-oxolaurate to ω-aminolauric acid and/or methyl ω-aminolaurate.

A microorganism according to the invention with increased activity of an enzyme E₂ in comparison to its wild type advantageously displays in comparison to its wild type decreased activity of an aldehyde dehydrogenase of EC 1.2.1.3, EC 1.2.1.4 or EC 1.2.1.5, which catalyses the following reaction:

ω-oxoalkanoic acid (ester)+NAD(P)⁺=ω-carboxyalkanoic acid (ester)+NAD(P)H+ H⁺ Such aldehyde dehydrogenases are in particular those which are listed below as specific E₅, and those which are listed below as preferred E₄ fatty alcohol oxidases of EC 1.1.3.20, AlkJ alcohol dehydrogenases of EC 1.1.99.- and alcohol dehydrogenases of EC 1.1.1.1 or EC 1.1.1.2 and catalyse at least the second of the two reactions mentioned there; such enzymes are also described below as enzymes E_(4*).

This has the technical effect that depletion of the ω-oxocarboxylic acid or the ω-oxocarboxylate ester to be aminated is prevented and hence more substrate is available for the ω-aminocarboxylic acid or ω-aminocarboxylate ester product formation.

The wording “in comparison to its wild type, decreased activity” is preferably understood to mean activity decreased by at least 50%, particularly preferably by at least 90%, more preferably by at least 99.9%, still more preferably by at least 99.99% and most preferably by at least 99.999% based on the wild type activity. The wording “decreased activity” also includes no detectable activity (“activity of nil”). The reduction of the activity of a specific enzyme can for example be effected by targetted mutation or by other measures known to those skilled in the art for reducing the activity of a specific enzyme. Further processes for reducing enzymatic activities in microorganisms are known to those skilled in the art. Molecular biological techniques in particular are suitable here. Those skilled in the art will find instructions for the modification and reduction of protein expression and enzymatic activity reduction associated therewith for Candida, in particular for interruption of specific genes in WO91/006660 and WO03/100013.

Microorganisms preferred according to the invention are characterized in that the reduction of the enzymatic activity is achieved by modification of a gene comprising a nucleic acid sequence coding for the aforementioned enzymes, wherein the modification is selected from the group comprising, preferably consisting of, insertion of foreign DNA into the gene, deletion at least of parts of the gene, point mutations in the gene sequence, RNA interference (siRNA), antisense RNA or modification (insertion, deletion or point mutations) of regulatory sequences which flank the gene. In this connection, foreign DNA should be understood to mean any DNA sequence which is “foreign” to the gene (and not to the organism). In this connection, it is particularly preferable that the gene is interrupted by insertion of a selection marker gene, so that the foreign DNA is a selection marker gene, wherein the insertion was preferably effected by homologous recombination into the gene locus. In this connection, it can be advantageous if the selection marker gene is extended with further functionalities which in turn enable subsequent removal from the gene. This can for example be achieved by recombination systems foreign to the organism, such as for example a Cre/loxP system or FRT (Flippase Recognition Target) system or the recombination system intrinsic to the organism.

The reduction of the activity of the microorganism according to the invention in comparison to its wild type is determined according to methods described above for the determination of the activity with use of as far as possible equal cell counts/concentrations, wherein the cells have been grown under the same conditions such as for example medium, gassing and stirring.

Enzyme E₃ Cofactor Recycling ω-Amination

For the production of an ω-amino-functionalized carboxylic acid or an ω-amino-functionalized carboxylate ester it can be advantageous if the second genetic modification comprises increased activity of an enzyme E₃ which catalyses the conversion of an α-ketocarboxylic acid to an amino acid. Preferably the enzyme E₃ is an amino acid dehydrogenase, such as for example serine dehydrogenases, aspartate dehydrogenases, phenylalanine dehydrogenases and glutamate dehydrogenases, particularly preferably an alanine dehydrogenase of EC 1.4.1.1.

Such preferable alanine dehydrogenases are selected from

EGR93259.1, YP_(—)004743277.1, YP_(—)004741620.1, YP_(—)004737294.1, YP_(—)002509853.1, YP_(—)002492255.1, YP_(—)002489845.1, YP_(—)002481919.1, YP_(—)001819330.1, YP_(—)004728333.1, ZP_(—)08670930.1, YP_(—)004672392.1, YP_(—)004467026.1, YP_(—)004326214.1, YP_(—)002349951.1, YP_(—)001674437.1, YP_(—)003921585.1, YP_(—)001699731.1, YP_(—)004720756.1, YP_(—)004719515.1, EGQ22316.1, EGQ21760.1, YP_(—)004689232.1, YP_(—)004698526.1, YP_(—)004694875.1, EGP67576.1, YP_(—)001832691.1, YP_(—)001760857.1, AEJ53875.1, AEJ42949.1, YP_(—)004392931.1, YP_(—)004404798.1, YP_(—)004374160.1, YP_(—)004303162.1, YP_(—)004196134.1, YP_(—)004178581.1, YP_(—)004163857.1, YP_(—)004161555.1, YP_(—)004099081.1, YP_(—)004101986.1, YP_(—)004042336.1, YP_(—)003994181.1, YP_(—)003966543.1, YP_(—)003913256.1, YP_(—)003825828.1, YP_(—)003806106.1, YP_(—)003686355.1, YP_(—)003678575.1, YP_(—)003654745.1, YP_(—)003651439.1, YP_(—)003637111.1, YP_(—)003631815.1, YP_(—)003300711.1, YP_(—)002886396.1, ZP_(—)03493991.1, YP_(—)001890813.1, YP_(—)001888849.1, YP_(—)001554753.1, YP_(—)001529018.1, YP_(—)001528954.1, YP_(—)001502090.1, YP_(—)001412833.1, YP_(—)001363812.1, YP_(—)923679.1, NP_(—)440110.1, ZP_(—)08640273.1, ZP_(—)08639751.1, ZP_(—)08637916.1, YP_(—)004171395.1, YP_(—)001366419.1, YP_(—)001327051.1, YP_(—)001262560.1, YP_(—)886996.1, YP_(—)882850.1, YP_(—)704410.1, YP_(—)703508.1, ZP_(—)08624689.1, YP_(—)001230376.1, P17557.1, P17556.1, CCB94892.1, CCB73698.1, YP_(—)001168635.1, YP_(—)004668736.1, YP_(—)911378.1, YP_(—)003686997.1, YP_(—)002263235.1, NP_(—)820115.1, YP_(—)004653761.1, YP_(—)004651159.1, YP_(—)003869397.1, YP_(—)004641708.1, YP_(—)004641134.1, YP_(—)001996597.1, YP_(—)001998297.1, YP_(—)001943676.1, YP_(—)001810799.1, YP_(—)004630087.1, YP_(—)004621893.1, YP_(—)004613083.1, ZP_(—)08621144.1, YP_(—)003954200.1, YP_(—)001372688.1, YP_(—)001233686.1, ZP_(—)08594848.1, ZP_(—)08586665.1, ZP_(—)08578896.1, ZP_(—)08575937.1, YP_(—)004604438.1, YP_(—)004600931.1, ZP_(—)08569139.1, 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ZP_(—)04608704.1, ZP_(—)04581931.1, ZP_(—)04555275.1, ZP_(—)04553607.1, ZP_(—)04545440.1, ZP_(—)04538537.1, YP_(—)002311919.1, ZP_(—)01052096.1, YP_(—)432286.1, ZP_(—)07039851.1, ZP_(—)07036831.1, ZP_(—)07035634.1, ZP_(—)06826623.1, ZP_(—)06202690.1, ZP_(—)06091438.1, ZP_(—)06060476.1, YP_(—)002955941.1, YP_(—)002764322.1, YP_(—)002761274.1, YP_(—)002754767.1, YP_(—)002605829.1, YP_(—)002544281.1, YP_(—)002453687.1, YP_(—)002444060.1, YP_(—)002369417.1, YP_(—)002365390.1, YP_(—)002297006.1, YP_(—)002233968.1, YP_(—)001861152.1, YP_(—)001850232.1, YP_(—)001827236.1, YP_(—)001815332.1, YP_(—)001661116.1, YP_(—)001647239.1, YP_(—)001643400.1, YP_(—)001625970.1, YP_(—)001584357.1, YP_(—)001488077.1, YP_(—)001473862.1, YP_(—)001450010.1, YP_(—)001444991.1, YP_(—)001424576.1, YP_(—)001422460.1, YP_(—)001376512.1, YP_(—)001373857.1, YP_(—)001217438.1, YP_(—)001155448.1, YP_(—)001117213.1, YP_(—)001094151.1, YP_(—)950353.1, YP_(—)949946.1, YP_(—)944887.1, YP_(—)854776.1, YP_(—)837848.1, YP_(—)795217.1, YP_(—)750481.1, YP_(—)746463.1, YP_(—)681383.1, YP_(—)673989.1, YP_(—)632321.1, YP_(—)624008.1, YP_(—)615612.1, YP_(—)611857.1, YP_(—)604242.1, YP_(—)562748.1, YP_(—)536656.1, YP_(—)517218.1, YP_(—)459264.1, YP_(—)382475.1, YP_(—)340233.1, YP_(—)295387.1, YP_(—)285355.1, YP_(—)204286.1, YP_(—)174267.1, YP_(—)165491.1, YP_(—)126314.1, YP_(—)111103.1, YP_(—)098760.1, YP_(—)082111.1, YP_(—)064280.1, YP_(—)064276.1, YP_(—)062161.1, YP_(—)056928.1, YP_(—)008485.1, YP_(—)005739.1, NP_(—)961822.1, NP_(—)953341.1, NP_(—)926915.1, NP_(—)875991.1, NP_(—)834329.1, NP_(—)830409.1, NP_(—)827683.1, NP_(—)694147.1, NP_(—)693109.1, NP_(—)682897.1, NP_(—)661601.1, NP_(—)621858.1, NP_(—)486395.1, NP_(—)385730.1, NP_(—)231539.1, ADL65712.1, XP_(—)003087064.1, YP_(—)003886520.1, YP_(—)003699559.1, YP_(—)003516134.1, ADI98200.1, BAI86717.1, YP_(—)003794343.1, YP_(—)003790454.1, ADI11356.1, YP_(—)003845821.1, ADK69870.1, YP_(—)003784546.1, CBW36497.1, CBW26165.1, YP_(—)003709979.1, CAQ50186.1, ZP_(—)06770463.1, CBK69442.1, YP_(—)003413835.1, YP_(—)003595089.1, ZP_(—)06807811.1, YP_(—)003582455.1, YP_(—)003464731.1, YP_(—)003496397.1, YP_(—)003421918.1, CBL07274.1, CBK64956.1, YP_(—)003508515.1, AAL87460.1, AAC23579.1, AAC23578.1, AAC23577.1, ACU78652.1, YP_(—)003471439.1, YP_(—)003452777.1, ZP_(—)06384971.1, ACY25368.1, ABC26869.1, AAP44334.1, EEZ80018.1, ZP_(—)05110458.1, 1PJB_A, ZP_(—)04717201.1, ZP_(—)04689103.1, ZP_(—)04658071.1, XP_(—)002364705.1, ACN89388.1, 2VHW_A, 2VHV_A, XP_(—)001324625.1, ABZ06259.1, ABR57171.1, CAO90307.1, CAM75354.1, CAA44791.1, BAA77513.1, EGR96638.1, EGR94699.1, ZP_(—)08693646.1, YP_(—)004740306.1, YP_(—)004738947.1, AEE73472.1, YP_(—)002478771.1, YP_(—)002018970.1, YP_(—)001953230.1, ZP_(—)08683223.1, YP_(—)004073823.1, EGQ99856.1, ZP_(—)08664912.1, EGQ79321.1, YP_(—)001681700.1, AEJ51356.1, YP_(—)004378292.1, YP_(—)004237802.1, YP_(—)004166920.1, YP_(—)004043011.1, YP_(—)003997728.1, YP_(—)002975437.1, YP_(—)002514072.1, YP_(—)001433829.1, YP_(—)001185975.1, YP_(—)004676549.1, YP_(—)004016358.1, YP_(—)911347.1, YP_(—)004658403.1, YP_(—)002015455.1, YP_(—)001996171.1, YP_(—)001998271.1, YP_(—)001960099.1, YP_(—)001942826.1, YP_(—)001130666.1, YP_(—)004608353.1, YP_(—)508400.1, YP_(—)374553.1, ZP_(—)06298411.1, ZP_(—)06044299.1, ZP_(—)04390473.1, ZP_(—)04055222.1, ZP_(—)03779980.1, ZP_(—)03729400.1, ZP_(—)03390832.1, YP_(—)004580682.1, YP_(—)001988281.1, YP_(—)644219.1, YP_(—)665459.1, NP_(—)895289.1, YP_(—)004275231.1, NP_(—)208189.1, BAJ60529.1, BAJ59008.1, BAJ57509.1, BAJ56032.1, ZP_(—)01254396.1, YP_(—)445036.1, EGL90046.1, YP_(—)004510847.1, ZP_(—)08450330.1, YP_(—)003387804.1, YP_(—)003058152.1, ZP_(—)03438664.1, ZP_(—)01884341.1, AEG33860.1, YP_(—)004429375.1, ZP_(—)08459444.1, ZP_(—)07909193.1, ZP_(—)07908670.1, EFT26139.1, EFT23947.1, EFT12708.1, EFT03750.1, EFS82814.1, EFS74272.1, EFS67128.1, ZP_(—)06844564.1, YP_(—)826658.1, YP_(—)001195249.1, YP_(—)003095978.1, YP_(—)469292.1, YP_(—)004442054.1, YP_(—)004461174.1, YP_(—)004055616.1, YP_(—)003576656.1, YP_(—)003094537.1, YP_(—)001295973.1, AEE71143.1, YP_(—)004447480.1, YP_(—)001978005.1, ZP_(—)08413507.1, ZP_(—)07820264.1, YP_(—)416780.1, EGI86036.1, YP_(—)003109321.1, YP_(—)001275268.1, YP_(—)380171.1, YP_(—)159073.1, YP_(—)004203456.1, YP_(—)003761844.1, YP_(—)040853.1, ZP_(—)08328557.1, CBL87253.1, CBL87167.1, YP_(—)004316768.1, EFS92548.1, YP_(—)001016505.1, EGG67688.1, YP_(—)003528837.1, YP_(—)002434942.1, YP_(—)117835.1, YP_(—)004150583.1, YP_(—)003755105.1, YP_(—)002526442.1, YP_(—)003120958.1, EGE94241.1, YP_(—)004345416.1, EFS79952.1, ZP_(—)06964253.1, EGE60050.1, CBZ52359.1, ADU40304.1, ADQ77229.1, YP_(—)003196038.1, YP_(—)144713.1, YP_(—)001304143.1, YP_(—)113082.1, ADO76516.1, YP_(—)003326349.1, YP_(—)003289755.1, YP_(—)003089327.1, ZP_(—)07911965.1, ZP_(—)05773583.1, ZP_(—)05765271.1, YP_(—)003154888.1, YP_(—)003142045.1, YP_(—)002280953.1, NP_(—)371963.1, NP_(—)422368.1, EGC98966.1, EGC76398.1, YP_(—)004263661.1, YP_(—)004252039.1, YP_(—)679036.1, YP_(—)499973.1, ZP_(—)08090745.1, ZP_(—)08108339.1, YP_(—)001531594.1, ZP_(—)01051588.1, NP_(—)646145.1, NP_(—)224146.1, ZP_(—)08054972.1, ZP_(—)08053009.1, YP_(—)003584878.1, ZP_(—)07939405.1, ZP_(—)03439290.1, ADU82392.1, ADU83943.1, ADU85424.1, ADU80668.1, YP_(—)001225733.1, YP_(—)003863039.1, ZP_(—)01061682.1, YP_(—)767568.1, ZP_(—)07865749.1, ZP_(—)06858058.1, YP_(—)628213.1, EFT81350.1, EFT66610.1, EFT51424.1, ZP_(—)04839161.1, ZP_(—)05633406.1, ZP_(—)05288381.1, AAR37813.1, EFS03282.1, EFS03278.1, YP_(—)004046539.1, ZP_(—)07749550.1, ZP_(—)07729731.1, ADN80650.1, ZP_(—)07088856.1, ZP_(—)07080219.1, ZP_(—)06949721.1, ZP_(—)05685436.1, YP_(—)002550450.1, YP_(—)803715.1, ZP_(—)07720023.1, ZP_(—)07469700.1, ZP_(—)07365619.1, ZP_(—)06924335.1, ZP_(—)06715776.1, ZP_(—)06303722.1, ZP_(—)06303721.1, ZP_(—)06264319.1, ZP_(—)06155528.1, ZP_(—)05745707.1, ZP_(—)04866244.1, ZP_(—)04199629.1, ZP_(—)04195783.1, ZP_(—)04067276.1, ZP_(—)03968868.1, ZP_(—)03963857.1, ZP_(—)03933079.1, ZP_(—)03497046.1, ZP_(—)03475134.1, ZP_(—)01890152.1, ZP_(—)01086712.1, ZP_(—)06021845.1, ZP_(—)02183427.1, ZP_(—)02162695.1, ZP_(—)02032824.1, ZP_(—)01993906.1, ZP_(—)01993127.1, ZP_(—)01983694.1, ZP_(—)01972527.1, ZP_(—)01819838.1, ZP_(—)01817962.1, ZP_(—)01740947.1, ZP_(—)01734991.1, ZP_(—)01694775.1, ZP_(—)01678972.1, ZP_(—)01468566.1, ZP_(—)01408749.1, ZP_(—)01386800.1, ZP_(—)01202184.1, ZP_(—)01174108.1, ZP_(—)01174047.1, ZP_(—)01118729.1, ZP_(—)01081268.1, ZP_(—)00998573.1, ZP_(—)00739793.1, YP_(—)002302140.1, ZP_(—)07358151.1, ZP_(—)06668925.1, ZP_(—)06668924.1, ZP_(—)06667106.1, ZP_(—)06324464.1, ZP_(—)06196777.1, ZP_(—)05114159.1, ZP_(—)05083968.1, ZP_(—)05070370.1, ZP_(—)05030022.1, ZP_(—)04673064.1, ZP_(—)04581752.1, ZP_(—)01052079.1, ZP_(—)07661104.1, ZP_(—)06077819.1, YP_(—)002835579.1, YP_(—)002267069.1, YP_(—)002129114.1, YP_(—)001929236.1, YP_(—)001910999.1, YP_(—)001854051.1, YP_(—)001094152.1, YP_(—)001044252.1, YP_(—)861818.1, YP_(—)915522.1, YP_(—)807371.1, YP_(—)353800.1, YP_(—)342402.1, YP_(—)065168.1, YP_(—)015797.1, YP_(—)005051.1, NP_(—)856449.1, NP_(—)661547.1, NP_(—)358448.1, YP_(—)003929442.1, YP_(—)003927769.1, ADO06185.1, ADO04689.1, ADL23243.1, YP_(—)003789202.1, ADJ79786.1, YP_(—)003516488.1, ADI97953.1, ADI35485.1, YP_(—)003716800.1, ZP_(—)00241359.1, YP_(—)003718040.1, CAQ49862.1, YP_(—)003282331.1, AAP97897.1, ACX99978.1, ACX98578.1, YP_(—)003472544.1, ZP_(—)06382734.1, EEZ79852.1, ZP_(—)05299989.1, ZP_(—)05299895.1, XP_(—)002367632.1, ZP_(—)03529835.1, ZP_(—)03517011.1, ZP_(—)03505783.1, XP_(—)001310698.1, ABK27691.1, CAB59281.2, in particular NP_(—)391071.1 (encoded by SEQ ID No. 11), BAI86717.1, YP_(—)004205024.1, ZP_(—)06873224.1, YP_(—)003974610.1, YP_(—)001422460.1, AEB25326.1, YP_(—)003921585.1, YP_(—)080482.1, ZP_(—)03054334.1, YP_(—)001488077.1, YP_(—)081348.1, YP_(—)003426902.1, NP_(—)243195.1, ZP_(—)08004522.1, YP_(—)003565624.1, YP_(—)004095847.1, YP_(—)003600348.1, ZP_(—)08006697.1, ZP_(—)04248389.1, YP_(—)174267.1, YP_(—)001376512.1, ZP_(—)04226233.1, ZP_(—)04100460.1, YP_(—)002369417.1, ZP_(—)03229411.1, ZP_(—)04110635.1, ZP_(—)04287684.1, ZP_(—)04172877.1, ZP_(—)04158983.1, ZP_(—)04219330.1, NP_(—)830409.1, YP_(—)003790454.1, ZP_(—)04184510.1, YP_(—)001642542.1, ZP_(—)04074263.1, ZP_(—)04319784.1, NP_(—)847074.1, YP_(—)001373857.1, ZP_(—)04122524.1, ZP_(—)03230841.1, YP_(—)082111.1, NP_(—)834329.1, YP_(—)002444060.1, ZP_(—)04170954.1, YP_(—)002453687.1, ZP_(—)04153266.1, ZP_(—)04302850.1, YP_(—)002365390.1, ZP_(—)04216141.1, ZP_(—)04298961.1, ZP_(—)00740055.1, ZP_(—)04277177.1, ZP_(—)04104350.1, ZP_(—)04176651.1, YP_(—)001647239.1, ZP_(—)04188247.1, ZP_(—)04149717.1, YP_(—)003794343.1, ZP_(—)04230016.1, YP_(—)001643400.1, ZP_(—)04209092.1, ZP_(—)04235899.1, YP_(—)003428808.1, ZP_(—)08005962.1, YP_(—)003599946.1, YP_(—)003565223.1, ZP_(—)01859623.1, YP_(—)004569425.1, ZP_(—)04432601.1, ZP_(—)03227314.1, YP_(—)003699559.1, ZP_(—)07709417.1, ZP_(—)01723571.1, NP_(—)244046.1, ZP_(—)08006365.1, ZP_(—)00738801.1, ZP_(—)04160852.1, ZP_(—)04166021.1, ZP_(—)04154769.1, ZP_(—)04109769.1, ZP_(—)04109049.1, ZP_(—)04108444.1, ZP_(—)04075249.1, ZP_(—)00741173.1, ZP_(—)00739793.1, ZP_(—)01174108.1, ZP_(—)01174047.1, ZP_(—)00241359.1, ZP_(—)04195783.1, ZP_(—)04199629.1, ZP_(—)04067276.1 and particularly preferably NP_(—)391071.1 (encoded by SEQ ID No. 11) and proteins with a polypeptide sequence wherein up to 60%, preferably up to 25%, particularly preferably up to 15%, in particular up to 10, 9, 8, 7, 6, 5, 4, 3, 2 or 1% of the amino acid residues compared to the aforementioned reference sequences are modified by deletion, insertion, substitution or a combination thereof and which still possess at least 50%, preferably 65%, particularly preferably 80%, in particular more than 90% of the activity of the protein with the corresponding, aforementioned reference sequence, wherein 100% activity of the reference protein is understood to mean the increasing of the activity of the cells used as a biocatalyst, i.e. the quantity of substance converted per unit time based on the cell quantity used (units per gram cell dry weight [U/g CDW]) in comparison to the activity of the biocatalyst in the absence of the reference protein, wherein the activity in this connection and in connection with the determination of the activity of the enzyme E₃ in general is understood to mean in particular the conversion of pyruvate to alanine.

Enzyme E₄ ω-Oxidation

For the production of an ω-amino-functionalized carboxylic acid or an ω-amino-functionalized carboxylate ester, it can be advantageous if the second genetic modification comprises increased activity of an enzyme E₄ which catalyses the conversion of ω-hydroxycarboxylic acids or ω-hydroxycarboxylate esters to the corresponding ω-oxocarboxylic acids or ω-oxocarboxylate esters. This increased activity of the enzyme E₄ can also be advantageous if the preparation of ω-oxocarboxylic acids, ω-oxocarboxylate esters, ω-carboxycarboxylic acid or ω-carboxycarboxylate esters is desired.

Should the microorganisms according to the invention be used in a process for the production of ω-oxocarboxylic acids or ω-oxocarboxylate esters or of ω-functionalized compounds derived from ω-oxocarboxylic acids or ω-oxocarboxylate esters such as for example ω-amino compounds, then it is advantageous if the microorganism, as already described above for E₂, displays decreased activity of an aldehyde dehydrogenase of EC 1.2.1.3, EC 1.2.1.4 or EC 1.2.1.5 in comparison to its wild type. In this connection, preferred enzymes E₄ are those which only catalyse the respective first-mentioned of the two reactions mentioned in the following section.

Specific Enzymes E₄

Preferably the enzyme E₄ is

a fatty alcohol oxidase of EC 1.1.3.20, which preferentially catalyses at least one of the following reactions, in particular the first-mentioned: ω-hydroxyalkanoic acid (ester)+O₂=ω-oxoalkanoic acid (ester)+H₂O₂ and ω-oxoalkanoic acid (ester)+O₂=ω-carboxyalkanoic acid (ester)+H₂O₂ or an AlkJ alcohol dehydrogenase of EC 1.1.99.-, which preferentially catalyses at least one of the following reactions, in particular the first-mentioned: ω-hydroxyalkanoic acid (ester)+oxidized acceptor=ω-oxoalkanoic acid (ester)+reduced acceptor and ω-oxoalkanoic acid (ester)+oxidized acceptor=ω-carboxyalkanoic acid (ester)+reduced acceptor or an alcohol dehydrogenase of EC 1.1.1.1 or EC 1.1.1.2, which preferentially catalyses at least one of the following reactions, in particular the first-mentioned: ω-hydroxyalkanoic acid (ester)+NAD(P)⁺=ω-oxoalkanoic acid (ester)+NAD(P)H+ H⁺ and ω-oxoalkanoic acid (ester)+NAD(P)⁺=ω-carboxyalkanoic acid (ester)+NAD(P)H+H⁺.

Such preferable fatty alcohol oxidases are selected from

AAS46878.1, ACX81419.1, AAS46879.1, CAB75353.1, AAS46880.1, XP_(—)712350.1, XP_(—)002422236.1, XP_(—)712386.1, EEQ43775.1, XP_(—)001525361.1, XP_(—)001386087.1, XP_(—)459506.2, CAB75351.1, CAB75352.1, XP_(—)001385255.2, EDK39369.2, XP_(—)001484086.1, XP_(—)002618046.1, XP_(—)002548766.1, XP_(—)002548765.1, XP_(—)003041566.1, XP_(—)003328562.1, XP_(—)001214264.1, XP_(—)001904377.1, XP_(—)658227.1, XP_(—)001591990.1, XP_(—)753079.1, XP_(—)002569337.1, XP_(—)001268562.1, XP_(—)003348911.1, EGP90120.1, XP_(—)001389382.1, EER37923.1, XP_(—)001264046.1, EGO58212.1, XP_(—)001554225.1, XP_(—)003298648.1, XP_(—)959005.1, XP_(—)002841296.1, XP_(—)001940486.1, EGR52262.1, EEQ89581.1, EGD99881.1, EFQ33355.1, XP_(—)001821106.1, XP_(—)002622231.1, EGG03784.1, EGC44059.1, XP_(—)003018036.1, XP_(—)003011696.1, EFY90752.1, XP_(—)001227812.1, XP_(—)758170.1, XP_(—)001243546.1, XP_(—)002479333.1, XP_(—)003344707.1, EFW14100.1, XP_(—)003071927.1, XP_(—)003171263.1, XP_(—)003051757.1, XP_(—)002147053.1, EEH19591.1, EEH50473.1, XP_(—)001792978.1, XP_(—)387094.1, EFY98644.1, XP_(—)002788971.1, XP_(—)002842592.1, EFX04185.1, XP_(—)003231449.1, XP_(—)001729067.1, CBX94189.1, XP_(—)001413535.1, ACF22878.1, B5WWZ9.1, XP_(—)002994642.1, XP_(—)002269629.1, XP_(—)002519938.1, XP_(—)002982582.1, NP_(—)001047464.1, EEC73620.1, XP_(—)002981110.1, XP_(—)002960521.1, NP_(—)566729.1, XP_(—)001541970.1, XP_(—)002967201.1, BAK00483.1, XP_(—)002182547.1, BAK02336.1, XP_(—)002454190.1, XP_(—)002328753.1, XP_(—)002867943.1, XP_(—)002285334.1, CAC87643.1, CAN71289.1, XP_(—)002454188.1, AAL31049.1, XP_(—)002464494.1, AAL31021.1, YP_(—)117187.1, XP_(—)002543430.1, CAA18625.1, XP_(—)002883430.1, NP_(—)193673.2, XP_(—)002529832.1, XP_(—)001753124.1, NP_(—)001142399.1, ACN27562.1, XP_(—)002464495.1, ACR36691.1, BAJ86655.1, B5WWZ8.1, NP_(—)001148058.1, ABR17814.1, EAY78905.1, NP_(—)194586.1, AAM63097.1, AAK64154.1, NP_(—)001064839.2, XP_(—)002869492.1, XP_(—)002314488.1, AAL31024.1, ZP_(—)06967355.1, AAP54248.2, XP_(—)002311685.1, ACF87929.1, YP_(—)907078.1, EGE07035.1, YP_(—)001849908.1, XP_(—)002464496.1, EEC67160.1, AAL31027.1, XP_(—)001761391.1, XP_(—)002961172.1, XP_(—)002528823.1, XP_(—)002966834.1, NP_(—)001176205.1, XP_(—)001763007.1, XP_(—)002272123.1, XP_(—)002889487.1, XP_(—)003003157.1, NP_(—)285451.1, EGG23219.1, NP_(—)171895.2, YP_(—)003395677.1, Q9ZWB9.1, ACF88407.1, ZP_(—)06413771.1, EEE51131.1, YP_(—)003835264.1, YP_(—)003397164.1, YP_(—)004081922.1, XP_(—)003294587.1, EEE51130.1, YP_(—)003647529.1, YP_(—)003647985.1, CBI29206.3, XP_(—)629786.1, ZP_(—)07964664.1, EEE57396.1, EEH09589.1, YP_(—)003265796.1, YP_(—)001840752.1, ZP_(—)08620775.1, ACR36076.1, ZP_(—)05043749.1, YP_(—)980677.1, ZP_(—)05043728.1, YP_(—)692894.1, NP_(—)710223.1, EEC67159.1, AAP03110.1, EFA85697.1, YP_(—)691805.1, YP_(—)551012.1, YP_(—)001174466.1, YP_(—)002796294.1, YP_(—)004716331.1, YP_(—)001019547.1, YP_(—)585737.1, AEA86007.1, YP_(—)960830.1, YP_(—)004743970.1, ZP_(—)03431349.1, ZP_(—)06448642.1, ZP_(—)07430351.1, NP_(—)215006.2, ZP_(—)03535393.1, ZP_(—)06801690.1, YP_(—)001849132.1, NP_(—)854165.1, ZP_(—)03427234.1, CBJ27378.1, NP_(—)334920.1, ZP_(—)08571383.1, YP_(—)728161.1, ZP_(—)01896040.1, ZP_(—)03530923.1, YP_(—)551306.1, YP_(—)003167456.1, YP_(—)606070.1, ZP_(—)06850167.1, ADP99095.1, YP_(—)907986.1, ZP_(—)04924166.1, ZP_(—)08139923.1, YP_(—)001270300.1, YP_(—)521830.1, YP_(—)003147410.1, YP_(—)002007173.1, ADR62464.1, YP_(—)004382294.1, NP_(—)747223.1, YP_(—)004687462.1, NP_(—)902159.1, ZP_(—)04936784.1, YP_(—)003914667.1, ZP_(—)01306356.1, ZP_(—)04750553.1, YP_(—)002875279.1, YP_(—)004704374.1, YP_(—)001671392.1, NP_(—)249055.1, ZP_(—)06876360.1, YP_(—)001345853.1, YP_(—)002437969.1, YP_(—)004356853.1, YP_(—)351075.1, CBI23676.3, YP_(—)001189668.1, YP_(—)001528881.1, YP_(—)001613612.1, YP_(—)001747218.1, YP_(—)003393002.1, YP_(—)001365074.1, ZP_(—)07778129.1, ZP_(—)07392715.1, YP_(—)001553329.1, YP_(—)262925.1, YP_(—)751961.1, YP_(—)564183.1, YP_(—)003811876.1, YP_(—)002356821.1, YP_(—)001051828.1, YP_(—)001837525.1, NP_(—)716513.1, ZP_(—)01915079.1, ZP_(—)02156621.1, YP_(—)001184631.1, YP_(—)001475595.1, ZP_(—)05042393.1, YP_(—)962228.1, YP_(—)001612275.1, ADV55625.1, YP_(—)001675797.1, YP_(—)003555260.1, ZP_(—)01075039.1, YP_(—)003812822.1, YP_(—)001503351.1, EFN52938.1, YP_(—)001759063.1, ZP_(—)06503577.1, YP_(—)871025.1, ZP_(—)08564919.1, YP_(—)002310162.1, YP_(—)732875.1, YP_(—)001092722.1, YP_(—)739324.1, XP_(—)002333995.1, NP_(—)085596.1, YP_(—)928870.1, EGD05748.1, NP_(—)443993.1, ZP_(—)08138057.1, ZP_(—)05041587.1, ZP_(—)07011380.1, YP_(—)001612684.1, ZP_(—)07669342.1, ZP_(—)06508361.1, ZP_(—)03423639.1, YP_(—)923293.1, ZP_(—)05061865.1, ZP_(—)08181496.1, YP_(—)559605.1, ZP_(—)06841320.1, ZP_(—)01620712.1, YP_(—)001896340.1, ZP_(—)03276650.1, YP_(—)004303194.1, ZP_(—)08180715.1, ZP_(—)06382740.1, ZP_(—)01034555.1, YP_(—)004604560.1, YP_(—)001020142.1, YP_(—)935375.1, ZP_(—)01546137.1, ZP_(—)07661079.1, YP_(—)001860640.1, ZP_(—)06052841.1, ZP_(—)01881170.1, ZP_(—)05781455.1, YP_(—)932732.1, ZP_(—)08119300.1, YP_(—)004715268.1, ZP_(—)03697402.1, YP_(—)004126957.1, ZP_(—)06703136.1, NP_(—)642445.1, ZP_(—)08273900.1, YP_(—)004524313.1, ZP_(—)01902993.1, YP_(—)001900094.1, AEA84888.1, YP_(—)004690289.1, NP_(—)714358.1, YP_(—)682471.1, YP_(—)003239.1, YP_(—)997465.1, YP_(—)003452130.1, ZP_(—)01739153.1, YP_(—)004219483.1, YP_(—)001761298.1, ZP_(—)01438251.1, CBI37146.3, ZP_(—)04748383.1, YP_(—)004362245.1, ZP_(—)05912795.1, YP_(—)003390234.1, YP_(—)003122799.1, CCB77579.1, EGB06416.1, ZP_(—)08389346.1, YP_(—)191496.1, ZP_(—)05224727.1, ZP_(—)01125614.1, YP_(—)466287.1, YP_(—)001368620.1, YP_(—)001380256.1, YP_(—)002361951.1, YP_(—)002756103.1, YP_(—)001801399.1, ZP_(—)06847140.1, YP_(—)003200069.1, YP_(—)001940247.1, YP_(—)001584322.1, ZP_(—)04679227.1, YP_(—)002493674.1, YP_(—)002135530.1, YP_(—)004290424.1, YP_(—)001772011.1, ZP_(—)08189046.1, ZP_(—)03423640.1, YP_(—)001834251.1, ZP_(—)01041752.1, YP_(—)001533410.1, YP_(—)269751.1, YP_(—)002432994.1, YP_(—)003694653.1, CAD47896.1, NP_(—)769359.1, YP_(—)004239460.1, YP_(—)004605221.1, YP_(—)001961214.1, YP_(—)001837513.1, YP_(—)004335962.1, YP_(—)004358600.1, ZP_(—)05050026.1, YP_(—)003202983.1, BAD03777.1, ZP_(—)02165013.1, NP_(—)774131.1, YP_(—)432169.1, ZP_(—)05000547.1, YP_(—)001261233.1, XP_(—)002593969.1, XP_(—)002603265.1, YP_(—)003342435.1, ZP_(—)01253183.1, EGO36831.1, YP_(—)001866737.1, YP_(—)001523879.1, YP_(—)133594.1, YP_(—)003768990.1, YP_(—)001237820.1, YP_(—)003133224.1, ZP_(—)01896771.1, ZP_(—)01865125.1, NP_(—)960319.1, YP_(—)826958.1, YP_(—)003326608.1, YP_(—)002219515.1, NP_(—)217926.1, ZP_(—)07441899.2, YP_(—)001208178.1, ADM42038.1, YP_(—)002433510.1, ZP_(—)08274313.1, EGO38668.1, ZP_(—)03393221.1, NP_(—)356358.1, ZP_(—)06055780.1, YP_(—)001684562.1, ZP_(—)08528157.1, BAD03162.1, YP_(—)001800712.1, ACL37106.1, YP_(—)883489.1, ZP_(—)01075202.1, NP_(—)969446.1, ZP_(—)01129577.1, YP_(—)001530285.1, ZP_(—)04746501.1, YP_(—)001341980.1, YP_(—)905003.1, ZP_(—)05218299.1, ZP_(—)08665577.1, preferably AAS46878.1, ACX81419.1, AAS46879.1, CAB75353.1, AAS46880.1, XP_(—)712350.1, XP_(—)002422236.1, XP_(—)712386.1, EEQ43775.1, XP_(—)001525361.1, XP_(—)001386087.1, XP_(—)459506.2, CAB75351.1, CAB75352.1, XP_(—)001385255.2, EDK39369.2, XP_(—)001484086.1, XP_(—)002618046.1, XP_(—)002548766.1, XP_(—)002548765.1, XP_(—)003041566.1, XP_(—)001214264.1, XP_(—)001904377.1, XP_(—)658227.1, XP_(—)001591990.1, XP_(—)753079.1, XP_(—)002569337.1, XP_(—)001268562.1, XP_(—)003348911.1, EGP90120.1, XP_(—)001389382.1, EER37923.1, XP_(—)001264046.1, EGO58212.1, XP_(—)001554225.1, XP_(—)003298648.1, XP_(—)959005.1, XP_(—)002841296.1, XP_(—)001940486.1, EGR52262.1, EEQ89581.1, EGD99881.1, EFQ33355.1, XP_(—)001821106.1, XP_(—)002622231.1, EGC44059.1, XP_(—)003018036.1, XP_(—)003011696.1, EFY90752.1, XP_(—)001227812.1, XP_(—)001243546.1, XP_(—)002479333.1, XP_(—)003344707.1, EFW14100.1, XP_(—)003071927.1, XP_(—)003171263.1, XP_(—)003051757.1, XP_(—)002147053.1, EEH19591.1, EEH50473.1, XP_(—)001792978.1, XP_(—)387094.1, EFY98644.1, XP_(—)002788971.1, XP_(—)002842592.1, EFX04185.1, XP_(—)003231449.1, CBX94189.1, XP_(—)001413535.1, XP_(—)001541970.1, XP_(—)002543430.1, EGE07035.1, XP_(—)003003157.1 and particularly preferably

AAS46878.1, ACX81419.1, AAS46879.1, CAB75353.1, AAS46880.1, XP_(—)712350.1, XP_(—)002422236.1, XP_(—)712386.1, EEQ43775.1, CAB75351.1, CAB75352.1, XP_(—)002548766.1, XP_(—)002548765.1,

and proteins with a polypeptide sequence wherein up to 60%, preferably up to 25%, particularly preferably up to 15%, in particular up to 10, 9, 8, 7, 6, 5, 4, 3, 2 or 1% of the amino acid residues compared to the aforementioned reference sequences are modified by deletion, insertion, substitution or a combination thereof and which still possess at least 50%, preferably 65%, particularly preferably 80%, in particular more than 90% of the activity of the protein with the corresponding, aforementioned reference sequence, wherein 100% activity of the reference protein is understood to mean the increasing of the activity of the cells used as a biocatalyst, i.e. the quantity of substance converted per unit time based on the cell quantity used (units per gram cell dry weight [U/g CDW]) in comparison to the activity of the biocatalyst in the absence of the reference protein, wherein the activity in this connection and in connection with the determination of the activity of the enzyme E₄ in general is understood to mean in particular the conversion of ω-oxolauric acid and/or methyl ω-oxolaurate to ω-carboxylauric acid and/or methyl w-carboxylaurate or the conversion of ω-hydroxylauric acid and/or methyl ω-hydroxylaurate to w-oxolauric acid and/or methyl ω-oxolaurate.

Such preferable AlkJ alcohol dehydrogenases are selected from

Q00593.1, Q9WWW2.1, ZP_(—)00957061.1, YP_(—)957894.1, CAC38030.1, YP_(—)694430.1, YP_(—)957725.1, YP_(—)001672216.1, YP_(—)552061.1, YP_(—)130410.1, ZP_(—)06155535.1, ZP_(—)01222730.1, YP_(—)691907.1, YP_(—)002297804.1, YP_(—)004283522.1, YP_(—)001234383.1, YP_(—)004435031.1, ZP_(—)05110316.1, ZP_(—)05042898.1, YP_(—)004466324.1, ZP_(—)08553549.1, YP_(—)004125220.1, ADI22536.1, ADI18461.1, YP_(—)003810975.1, YP_(—)662346.1, YP_(—)004427557.1, YP_(—)692606.1, ZP_(—)05043291.1, YP_(—)440752.1, ZP_(—)02386160.1, ZP_(—)04763547.1, ZP_(—)02361232.1, YP_(—)003376674.1, ZP_(—)02354055.1, ZP_(—)05085930.1, ADQ00130.1, YP_(—)003643016.1, ZP_(—)05040520.1, YP_(—)691922.1, AAX23098.1, BAD07371.1, NP_(—)104379.1, YP_(—)002551960.1, YP_(—)003908558.1, YP_(—)987903.1, ZP_(—)05785860.1, YP_(—)004145612.1, YP_(—)004140926.1, CAZ88300.1, ZP_(—)05041901.1, YP_(—)533645.1, ZP_(—)01754259.1, CBA31223.1, YP_(—)87542.1, YP_(—)106852.1, ZP_(—)08402506.1, ZP_(—)05055020.1, ZP_(—)02400829.1, YP_(—)104747.1, ZP_(—)02409412.1, YP_(—)001057269.1, YP_(—)004229837.1, YP_(—)294429.1, YP_(—)001028112.1, ZP_(—)02479747.1, YP_(—)002874799.1, ZP_(—)03541051.1, YP_(—)003606536.1, ZP_(—)02887167.1, YP_(—)001795572.1, YP_(—)487451.1, ACZ62814.1, YP_(—)560809.1, ZP_(—)02167462.1, YP_(—)004482869.1, YP_(—)001581248.1, ZP_(—)07374066.1, YP_(—)001203981.1, ZP_(—)06840259.1, ZP_(—)01915145.1, NP_(—)774525.1, ZP_(—)03561080.1, YP_(—)001208258.1, YP_(—)001897374.1, YP_(—)001413909.1, YP_(—)366469.1, YP_(—)521854.1, YP_(—)004490642.1, YP_(—)003280349.1, ZP_(—)03588744.1, YP_(—)001562229.1, YP_(—)001120981.1, ZP_(—)03574970.1, YP_(—)004234225.1, ZP_(—)02377531.1, ZP_(—)02149954.1, YP_(—)001237360.1, ZP_(—)03266156.1, YP_(—)782821.1, YP_(—)004754039.1, BAB61732.1, ZP_(—)07046388.1, ZP_(—)02145452.1, BAF45123.1, YP_(—)002129953.1, YP_(—)003812439.1, ZP_(—)01055291.1, BAF45124.1, EGH71399.1, ZP_(—)05060389.1, ZP_(—)05090872.1, BAF45126.1, BAB07804.1, ZP_(—)06053464.1, YP_(—)001238278.1, ZP_(—)04944469.1, YP_(—)001171160.1, YP_(—)002984373.1, YP_(—)002237649.1, ZP_(—)08276443.1, BAF98451.1, ZP_(—)05124197.1, YP_(—)568640.1, ZP_(—)05785341.1, NP_(—)769037.1, YP_(—)370657.1, YP_(—)775005.1, ZP_(—)02911119.1, YP_(—)165460.1, ZP_(—)02891796.1, YP_(—)622328.1, ZP_(—)07675057.1, YP_(—)001901188.1, YP_(—)003592183.1, ZP_(—)02361040.1, NP_(—)518244.1, YP_(—)001809673.1, NP_(—)947032.1, YP_(—)001766369.1, YP_(—)002255997.1, ZP_(—)04940241.1, YP_(—)004012032.1, YP_(—)841049.1, YP_(—)002983249.1, YP_(—)003643276.1, YP_(—)003855487.1, YP_(—)003778137.1, ZP_(—)02361104.1, CBA30511.1, ZP_(—)05781295.1, YP_(—)756865.1, ZP_(—)02461782.1, YP_(—)002007988.1, YP_(—)004110133.1, YP_(—)002229680.1, ZP_(—)02386040.1, YP_(—)004684069.1, YP_(—)373268.1, YP_(—)440614.1, NP_(—)421441.1, YP_(—)264896.1, YP_(—)004362617.1, ZP_(—)06053847.1, YP_(—)366538.1, YP_(—)003812285.1, YP_(—)004154520.1, ZP_(—)01901081.1, ZP_(—)02372179.1, ZP_(—)02453559.1, ADP98564.1, YP_(—)003747084.1, ZP_(—)02487888.1, ZP_(—)01768075.1, ZP_(—)02400664.1, YP_(—)106680.1, YP_(—)724753.1, YP_(—)002907583.1, YP_(—)004482470.1, YP_(—)167582.1, YP_(—)270109.1, YP_(—)004362333.1, ZP_(—)02504034.1, YP_(—)003189363.1, YP_(—)973212.1, ZP_(—)00952746.1, YP_(—)459665.1, YP_(—)777218.1, YP_(—)581107.1, ZP_(—)01878091.1, ZP_(—)01057973.1, YP_(—)002913124.1, ZP_(—)01035570.1, YP_(—)001777560.1, YP_(—)552627.1, ZP_(—)02890876.1, YP_(—)587146.1, YP_(—)004141814.1, YP_(—)001685369.1, ZP_(—)05343380.1, NP_(—)886000.1, ZP_(—)04942359.1, ZP_(—)01913732.1, ZP_(—)08244266.1, YP_(—)002233254.1, ZP_(—)01816670.1, YP_(—)837233.1, ZP_(—)07478008.1, ZP_(—)01985205.1, ZP_(—)07473972.1, ZP_(—)01067090.1, ZP_(—)01867788.1, ZP_(—)01754024.1, EGM19144.1, ZP_(—)07741283.1, ZP_(—)06876839.1, YP_(—)002395287.1, ZP_(—)07795498.1, NP_(—)102692.1, NP_(—)252789.1, YP_(—)004451100.1, ZP_(—)01305514.1, YP_(—)002438481.1, ZP_(—)04930310.1, YP_(—)001810189.1, YP_(—)104187.1, ZP_(—)01367534.1, YP_(—)001346382.1, ZP_(—)01878466.1, YP_(—)789017.1, 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ZP_(—)01040714.1, ZP_(—)04717111.1, YP_(—)002422932.1, YP_(—)003506115.1, ZP_(—)01444019.1, ZP_(—)03587285.1, YP_(—)771439.1, YP_(—)001947593.1, YP_(—)001049712.1, YP_(—)003979888.1, YP_(—)001553786.1, YP_(—)003980878.1, YP_(—)001578274.1, YP_(—)472442.1, YP_(—)778292.1, EGE56670.1, YP_(—)002779312.1, YP_(—)432169.1, YP_(—)560963.1, YP_(—)001265285.1, YP_(—)002822699.1, YP_(—)002278091.1, ZP_(—)08632361.1, YP_(—)002229178.1, ZP_(—)06840392.1, ZP_(—)05069105.1, ZP_(—)00998644.1, YP_(—)004487901.1, YP_(—)680905.1, YP_(—)728088.1, YP_(—)001985833.1, YP_(—)002007099.1, ZP_(—)05066777.1, ZP_(—)01551182.1, YP_(—)002973332.1, ZP_(—)04681414.1, ZP_(—)07675148.1, AEH83964.1, YP_(—)004692042.1, CBJ36337.1, EGP48473.1, ZP_(—)03585612.1, YP_(—)001369428.1, YP_(—)001897527.1, AEG08472.1, YP_(—)001166065.1, NP_(—)437018.1, NP_(—)294689.1, YP_(—)002541437.1, YP_(—)004692953.1, NP_(—)107484.1, YP_(—)995681.1, YP_(—)765267.1, YP_(—)166223.1, ZP_(—)01740635.1, YP_(—)001234127.1, ZP_(—)02186681.1, 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ZP_(—)02165272.1, YP_(—)701696.1, ZP_(—)04935724.1, ZP_(—)02191362.1, ZP_(—)01740154.1, ZP_(—)07662819.1, NP_(—)103908.1, YP_(—)003159313.1, YP_(—)003197010.1, ZP_(—)02152342.1, YP_(—)001907189.1, YP_(—)004387414.1, YP_(—)001413869.1, ZP_(—)01916549.1, ZP_(—)03264661.1, AAY82840.1, YP_(—)003277969.1, YP_(—)767433.1, ZP_(—)01226234.1, EGE55950.1, NP_(—)882474.1, ZP_(—)04680938.1, YP_(—)004417965.1, ZP_(—)01367142.1, EGM13684.1, YP_(—)001262083.1, ZP_(—)01881606.1, ZP_(—)01002680.1, YP_(—)003606679.1, YP_(—)001868359.1, ZP_(—)01446736.1, YP_(—)004141411.1, YP_(—)002438878.1, YP_(—)002500414.1, EGP55675.1, ZP_(—)08405873.1, YP_(—)002975318.1, YP_(—)002823637.1, ZP_(—)02188786.1, YP_(—)004617386.1, ABL61001.1, YP_(—)004190679.1, YP_(—)004418710.1, YP_(—)001264994.1, NP_(—)252399.1, ACA21517.1, YP_(—)002541208.1, YP_(—)001369943.1, YP_(—)789454.1, YP_(—)004688060.1, YP_(—)611623.1, ZP_(—)07795086.1, ZP_(—)04929943.1, YP_(—)004444316.1, ZP_(—)01866687.1, ZP_(—)05973466.1, YP_(—)004353327.1, 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YP_(—)001042739.1, YP_(—)133405.1, ZP_(—)05180516.1, ZP_(—)05174702.1, ZP_(—)01438051.1, ZP_(—)04590345.1, ZP_(—)08411937.1, NP_(—)356519.2, ZP_(—)00964019.1, ZP_(—)00998343.1, ZP_(—)05181994.1, YP_(—)004107969.1, ZP_(—)02168070.1, ZP_(—)01750865.1, YP_(—)574504.1, YP_(—)004579902.1, YP_(—)104440.1, ZP_(—)05452167.1, ZP_(—)05342702.1, YP_(—)001862883.1, YP_(—)004538242.1, ZP_(—)07471513.1, ZP_(—)05169558.1, ZP_(—)00956995.1, ZP_(—)05096699.1, YP_(—)004610916.1, ZP_(—)01218118.1, AAU95210.1, ZP_(—)02405087.1, ZP_(—)04890639.1, YP_(—)352237.1, ZP_(—)02413594.1, ZP_(—)07474023.1, NP_(—)541317.1, YP_(—)001993222.1, ZP_(—)08199001.1, YP_(—)471839.1, ZP_(—)02492080.1, ZP_(—)04901176.1, ZP_(—)06915396.1, ZP_(—)07474845.1, ZP_(—)07477743.1, YP_(—)004152647.1, YP_(—)004755056.1, ZP_(—)05086419.1, YP_(—)004577547.1, ACD99850.1, YP_(—)980426.1, ZP_(—)05457072.1, ZP_(—)05936041.1, NP_(—)700124.1, ADT85599.1, YP_(—)110012.1, ZP_(—)05076113.1, YP_(—)001068288.1, ZP_(—)02457871.1, ZP_(—)01014169.1, EGE60620.1, YP_(—)001346810.1, YP_(—)003408795.1, YP_(—)003769675.1, YP_(—)001257876.1, EGH93583.1, ZP_(—)01442222.1, YP_(—)331617.1, ZP_(—)05636703.1, YP_(—)001594896.1, YP_(—)002822967.1, YP_(—)118823.1, ZP_(—)01878717.1, ZP_(—)07375284.1, YP_(—)001371250.1, ZP_(—)07658682.1, YP_(—)002898825.1, ZP_(—)01547199.1, YP_(—)223070.1, ZP_(—)05161482.1, ZP_(—)04679742.1, YP_(—)002778618.1, ZP_(—)01626756.1, ZP_(—)05101564.1, YP_(—)002947374.1, NP_(—)385053.1, YP_(—)001328117.1, YP_(—)004493948.1, YP_(—)003339515.1, YP_(—)004699488.1, ZP_(—)05101969.1, YP_(—)485352.1, ZP_(—)01746033.1, ZP_(—)06712293.1, ZP_(—)01158125.1, ZP_(—)01058616.1, ZP_(—)05739755.1, NP_(—)949067.1, ZP_(—)02364657.1, YP_(—)570690.1, YP_(—)001208663.1, ZP_(—)02357557.1, ZP_(—)04751682.1, YP_(—)001326253.1, YP_(—)487666.1, ZP_(—)05167919.1, ADI18237.1, YP_(—)002825245.1, ZP_(—)02144858.1, ZP_(—)02188790.1, ZP_(—)06794586.1, YP_(—)001809828.1, YP_(—)997974.1, YP_(—)001476791.1, ZP_(—)08635286.1, YP_(—)676287.1, ZP_(—)07308228.1, ZP_(—)04596242.1, YP_(—)001622726.1, NP_(—)699590.1, ZP_(—)01446884.1, YP_(—)001168504.1, ZP_(—)01616388.1, ZP_(—)05117189.1, ZP_(—)05876432.1, ADT64694.1, ZP_(—)01754911.1, ZP_(—)05880498.1, ZP_(—)02360829.1, ZP_(—)06052433.1, ZP_(—)08663540.1, YP_(—)003768966.1, ZP_(—)02165422.1, ZP_(—)00960985.1, ZP_(—)07026655.1, YP_(—)001753039.1, YP_(—)371288.1, YP_(—)002974725.1, YP_(—)776880.1, ZP_(—)05784963.1, ZP_(—)05124380.1, YP_(—)459030.1, ZP_(—)05090690.1, ZP_(—)05064893.1, ZP_(—)02367982.1, ZP_(—)01890564.1, NP_(—)541848.1, ZP_(—)00960263.1, ZP_(—)02961617.1, YP_(—)001242097.1, ZP_(—)05838258.1, in particular Q00593.1, Q9WWW2.1, ZP_(—)00957061.1, YP_(—)957894.1, CAC38030.1, YP_(—)694430.1, YP_(—)957725.1, YP_(—)001672216.1, YP_(—)552061.1, YP_(—)130410.1, ZP_(—)06155535.1, ZP_(—)01222730.1, YP_(—)691907.1, YP_(—)002297804.1, YP_(—)004283522.1, YP_(—)001234383.1, YP_(—)004435031.1, ZP_(—)05110316.1, ZP_(—)05042898.1, YP_(—)004466324.1, ZP_(—)08553549.1, YP_(—)004125220.1, ADI22536.1, ADI18461.1, YP_(—)003810975.1, YP_(—)662346.1, YP_(—)004427557.1, YP_(—)692606.1, ZP_(—)05043291.1, YP_(—)440752.1, ZP_(—)02386160.1, ZP_(—)04763547.1, ZP_(—)02361232.1, YP_(—)003376674.1, ZP_(—)02354055.1, ZP_(—)05085930.1, ADQ00130.1, YP_(—)003643016.1, ZP_(—)05040520.1, YP_(—)691922.1, AAX23098.1, BAD07371.1, NP_(—)104379.1, YP_(—)002551960.1, YP_(—)003908558.1, YP_(—)987903.1, ZP_(—)05785860.1, YP_(—)004145612.1, YP_(—)004140926.1, CAZ88300.1, and particularly preferably

Q00593.1, Q9WWW2.1, ZP_(—)00957061.1, YP_(—)957894.1, CAC38030.1, YP_(—)694430.1, YP_(—)957725.1, YP_(—)001672216.1.

and proteins with a polypeptide sequence wherein up to 60%, preferably up to 25%, particularly preferably up to 15%, in particular up to 10, 9, 8, 7, 6, 5, 4, 3, 2 or 1% of the amino acid residues compared to the aforementioned reference sequences are modified by deletion, insertion, substitution or a combination thereof and which still possess at least 50%, preferably 65%, particularly preferably 80%, in particular more than 90% of the activity of the protein with the corresponding, aforementioned reference sequence, wherein 100% activity of the reference protein is understood to mean the increasing of the activity of the cells used as a biocatalyst, i.e. the quantity of substance converted per unit time based on the cell quantity used (units per gram cell dry weight [U/g CDW]) in comparison to the activity of the biocatalyst in the absence of the reference protein, wherein the activity in this connection is understood to mean in particular the conversion of ω-oxolauric acid and/or methyl ω-oxolaurate to ω-carboxylauric acid and/or methyl ω-carboxylaurate or the conversion of ω-hydroxylauric acid and/or methyl w-hydroxylaurate to ω-oxolauric acid and/or methyl ω-oxolaurate.

Such preferable alcohol dehydrogenases of EC 1.1.1.1 or EC 1.1.1.2 are selected from AdhE, AdhP, YjgB, YqhD, GIdA, EutG, YiaY, AdhE, AdhP, YhhX, YahK, HdhA, HisD, SerA, Tdh, Ugd, Udg, Gmd, YefA, YbiC, YdfG, YeaU, TtuC, YeiQ, YgbJ, YgcU, YgcT, YgcV, YggP, YgjR, YliI, YqiB, YzzH, LdhA, GapA, Epd, Dld, GatD, Gcd, GlpA, GlpB, GlpC, GlpD, GpsA and YphC from bacteria, in particular E. coli

and proteins with a polypeptide sequence wherein up to 60%, preferably up to 25%, particularly preferably up to 15%, in particular up to 10, 9, 8, 7, 6, 5, 4, 3, 2 or 1% of the amino acid residues compared to the aforementioned reference sequences are modified by deletion, insertion, substitution or a combination thereof and which still possess at least 50%, preferably 65%, particularly preferably 80%, in particular more than 90% of the activity of the protein with the corresponding, aforementioned reference sequence, wherein 100% activity of the reference protein is understood to mean the increasing of the activity of the cells used as a biocatalyst, i.e. the quantity of substance converted per unit time based on the cell quantity used (units per gram cell dry weight [U/g CDW]) in comparison to the activity of the biocatalyst in the absence of the reference protein, wherein the activity in this connection is understood to mean in particular the conversion of ω-oxolauric acid and/or methyl ω-oxolaurate to ω-carboxylauric acid and/or methyl ω-carboxylaurate or the conversion of ω-hydroxylauric acid and/or methyl ω-hydroxylaurate to ω-oxolauric acid and/or methyl ω-oxolaurate.

WO2010062480 A2 describes, particularly in practical examples 3, 4, 6 and 7, microorganisms which compared to their wild type are capable of forming more fatty acids and fatty acid derivatives, in particular fatty alcohols, from at least one simple carbon source. The document also describes enzymes F₄ preferred according to the invention and the sequences thereof in particular in FIG. 10 and practical examples 2 to 7.

Enzyme E₅ ω-Oxidation 2

For the production of an (β-carboxy-functionalized carboxylic acid or an ω-carboxy-functionalized carboxylate ester it can be advantageous if the second genetic modification comprises increased activity of an enzyme E₅ which catalyses the conversion of ω-oxocarboxylic acids or ω-oxocarboxylate esters to the corresponding ω-carboxycarboxylic acids or ω-carboxycarboxylate esters.

Specific Enzymes E₅

Preferably the enzyme E₅ is an aldehyde dehydrogenase of EC 1.2.1.3, EC 1.2.1.4 or EC 1.2.1.5, which preferentially catalyses the following reaction: ω-oxoalkanoic acid (ester)+NAD(P)⁺=ω-carboxyalkanoic acid (ester)+NAD(P)H⁺

Such preferable aldehyde dehydrogenases are selected from Prr, Usg, MhpF, AstD, GdhA, FrmA, Feab, Asd, Sad, PuuE, GabT, YgaW, BetB, PutA, PuuC, FeaB, AldA, Prr, EutA, GabD, AldB, TynA and YneI from bacteria, in particular E. coli

and proteins with a polypeptide sequence wherein up to 60%, preferably up to 25%, particularly preferably up to 15%, in particular up to 10, 9, 8, 7, 6, 5, 4, 3, 2 or 1% of the amino acid residues compared to the aforementioned reference sequences are modified by deletion, insertion, substitution or a combination thereof and which still possess at least 50%, preferably 65%, particularly preferably 80%, in particular more than 90% of the activity of the protein with the corresponding, aforementioned reference sequence, wherein 100% activity of the reference protein is understood to mean the increasing of the activity of the cells used as a biocatalyst, i.e. the quantity of substance converted per unit time based on the cell quantity used (units per gram cell dry weight [U/g CDW]) in comparison to the activity of the biocatalyst in the absence of the reference protein, wherein the activity in this connection and in connection with the determination of the activity of the enzyme E₅ in general is understood to mean in particular the conversion of ω-oxolauric acid and/or methyl ω-oxolaurate to ω-carboxylauric acid and/or methyl ω-carboxylaurate. alkL

In general, it can be advantageous for the microorganism according to the invention if it can secrete the ω-functionalized carboxylic acids and ω-functionalized carboxylate esters formed from the simple carbon source rapidly into the medium.

The organism advantageously achieves this in that the second genetic modification additionally comprises that the microorganism compared to its wild type forms more alkL gene product.

In connection with the present invention, the term “alkL gene product” is understood to mean proteins which fulfil at least one of the following two conditions:

1.) the protein is identified as a member of the superfamily of the OmpW proteins (protein family 3922 in the “Conserved Domain Database” (CDD) of the “National Center for Biotechnology Information” (NCBI)), where this assignment is made by alignment of the amino acid sequence of the protein with the database entries present in the CDD of the NCBI, which were deposited up to the 22.03.2010, with use of the standard search parameters, an e-value smaller than 0.01 and with use of the algorithm “blastp 2.2.23+”, 2.) in a search for conserved protein domains contained in the amino acid sequence concerned in the NCBI CDD (version 2.20) by means of RPS-BLAST, the presence of the conserved domain “OmpW, Outer membrane protein W” (COG3047) is identified with an e-value of less than 1×10⁻⁵ (“domain hit”).

Preferred gene products contained in the microorganism according to the invention alkL are characterized in that the production of the alkL gene product in the native host is induced by dicyclopropyl ketone; in this connection, it is also preferable that the expression of the alkL gene takes place as part of a group of genes, for example in a regulon such as for example an operon.

AlkL gene products contained in the microorganism according to the invention are preferably encoded by alkL genes from organisms selected from the group of the gram-negative bacteria, in particular the group containing, preferably consisting of, Pseudomonas sp., Azotobacter sp., Desulfitobacterium sp., Burkholderia sp., preferably Burkholderia cepacia, Xanthomonas sp., Rhodobacter sp., Ralstonia sp., Delftia sp. and Rickettsia sp., Oceanicaulis sp., Caulobacter sp., Marinobacter sp. and Rhodopseudomonas sp., preferably Pseudomonas putida, Oceanicaulis alexandrii, Marinobacter aquaeolei, in particular Pseudomonas putida GPo1 and P1, Oceanicaulis alexandrii HTCC2633, Caulobacter sp. K₃₁ and Marinobacter aquaeolei VT8. Quite especially preferred in this connection are alkL gene products encoded by the alkL genes from Pseudomonas putida GPo1 and P1, which are represented by Seq ID No. 1 and Seq ID No. 3, and proteins with polypeptide sequence Seq ID No. 2, Seq ID No. 4, Seq ID No. 5, Seq ID No. 6 or Seq ID No. 7 or with a polypeptide sequence wherein up to 60%, preferably up to 25%, particularly preferably up to 15%, in particular up to 10, 9, 8, 7, 6, 5, 4, 3, 2 or 1% of the amino acid residues are modified compared to Seq ID No. 2, Seq ID No. 4, Seq ID No. 5, Seq ID No. 6 or Seq ID No. 7 by deletion, insertion, substitution or a combination thereof and which still possess at least 50%, preferably 65%, particularly preferably 80%, in particular more than 90% of the activity of the protein with the respective reference sequence Seq ID No. 2, Seq ID No. 4, Seq ID No. 5, Seq ID No. 6 or Seq ID No. 7, wherein 100% activity of the reference protein is understood to mean the increasing of the activity of the cells used as a biocatalyst, i.e. the quantity of substance converted per unit time based on the cell quantity used (units per gram cell dry weight [U/g CDW]) in comparison to the activity of the biocatalyst in the absence of the reference protein, this being in a system as described in the practical examples, wherein glucose is converted to ω-aminolauric acid in an E. coli cell. A method of choice for the determination of the synthesis level can be found in the practical examples.

For the definition of the units, the definition usual in enzyme kinetics applies here: 1 unit of biocatalyst converts 1 μmol of substrate to the product in one minute.

1 U=1 μmol/min.

First Genetic Modification for Carboxylic Acid- and Carboxylate Ester-Synthesis

According to the invention, the microorganisms have a first genetic modification, so that compared to their wild type they are capable of forming more carboxylic acids and carboxylate ester from at least one simple carbon source.

In this connection, it is preferable according to the invention that the first genetic modification is, compared to the enzymatic activity of the wild type of the microorganism, increased activity of at least one of the enzymes selected from the group

E_(i) Acyl-ACP (acyl carrier protein) thioesterase, preferably of EC 3.1.2.14 or EC 3.1.2.22, which catalyses the hydrolysis of an acyl-acyl carrier protein thioester, E_(ii) Acyl-CoA (coenzyme A) thioesterase, preferably of EC 3.1.2.2, EC 3.1.2.18, EC 3.1.2.19, EC 3.1.2.20 or EC 3.1.2.22, which catalyses the hydrolysis of an acyl-coenzyme A thioester, E_(iib) Acyl-CoA (coenzyme A):ACP (acyl carrier protein) transacylase, which preferentially catalyses a reaction wherein a CoA thioester is converted into an ACP thioester, E_(iii) Polyketide synthase, which catalyses a reaction which is also involved in the synthesis of carboxylic acids and carboxylate esters, and E_(iv) Hexanoic acid synthase, a specialized fatty acid synthase of the FAS-I type, which catalyses the synthesis of hexanoic acid from 2 molecules of malonyl-coenzyme A and one molecule of acetyl-coenzyme A.

Specific Enzymes E₁

The reaction catalysed by E_(i) differs from that catalysed by E_(ii) only in that instead of an acyl-acyl carrier protein thioester an acyl-coenzyme A thioester is hydrolysed. It is obvious that because of significant side-activity many of the said enzymes E_(i) can also be used as E_(ii) and vice versa.

In cells preferred according to the invention, the enzyme E_(i) is one which comprises sequences selected from:

AAC72881.1, ABB71579.1, CAC19934.1, AAC49180.1 (encoded by SEQ ID No. 10), AAC49783.1, AAC49179.1, CAB60830.1, ABB71581.1, AAC49269.1, CAC19933.1, CAA54060.1, AAC72882.1, Q39513.1, AAC49784.1, ABO38558.1, ABO38555.1, ABO38556.1, ABO38554.1, ADB79568.1, ADB79569.1, ACQ57188.1, ACQ57189.1, ABK96561.1, ACQ63293.1, ACQ57190.1, Q9SQI3.1, ABU96744.1, ABC47311.1, XP_(—)002324962.1, AAD01982.1, AAB51525.1, ACV40757.1, XP_(—)002309244.1, CBI28125.3, ABD91726.1, XP_(—)002284850.1, XP_(—)002309243.1, XP_(—)002515564.1, ACR56792.1, ACR56793.1, XP_(—)002892461.1, ABI18986.1, NP_(—)172327.1, CAA85387.1, CAA85388.1, ADA79524.1, ACR56795.1, ACR56794.1, CAN81819.1, ACF17654.1, AAB71729.1, ABH11710.1, ACQ57187.1, AAX51637.1, AAB88824.1, AAQ08202.1, AAB71731.1, AAX51636.1, CAC80370.1, CAC80371.1, AAG43858.1, ABD83939.1, AAD42220.2, AAG43860.1, AAG43861.1, AAG43857.1, AAL15645.1, AAB71730.1, NP_(—)001068400.1, EAY86877.1, NP_(—)001056776.1, XP_(—)002436457.1, NP_(—)001149963.1, ACN27901.1, EAY99617.1, ABL85052.1, XP_(—)002437226.1, NP_(—)001151366.1, ACF88154.1, NP_(—)001147887.1, XP_(—)002453522.1, BAJ99650.1, EAZ37535.1, EAZ01545.1, AAN17328.1, EAY86884.1, EEE57469.1, Q41635.1, AAM09524.1, Q39473.1, NP_(—)001057985.1, AAC49001.1, XP_(—)001752161.1, XP_(—)001770108.1, XP_(—)001784994.1, XP_(—)002318751.1, NP_(—)001047567.1, XP_(—)002322277.1, XP_(—)002299627.1, XP_(—)002511148.1, CBI15695.3, XP_(—)002299629.1, XP_(—)002280321.1, CAN60643.1, XP_(—)002459731.1, XP_(—)002975500.1, XP_(—)002962077.1, XP_(—)001773771.1, NP_(—)001151014.1, XP_(—)002317894.1, XP_(—)002971008.1, XP_(—)001774723.1, XP_(—)002280147.1, XP_(—)002526311.1, XP_(—)002517525.1, XP_(—)001764527.1, ABI20759.1, BAD73184.1, XP_(—)002987091.1, XP_(—)002985480.1, CBI26947.3, ABI20760.1, XP_(—)002303055.1, XP_(—)002885681.1, ADH03021.1, XP_(—)002532744.1, EAY74210.1, EEC84846.1, EEE54649.1, AAG35064.1, AAC49002.1, CAD32683.1, ACF78226.1, BAJ96402.1, XP_(—)002462626.1, NP_(—)001130099.1, XP_(—)002462625.1, ABX82799.3, Q42712.1, NP_(—)193041.1, AAB51524.1, NP_(—)189147.1, ABR18461.1, XP_(—)002863277.1, AAC72883.1, AAA33019.1, CBI40881.3, XP_(—)002262721.1, AAB51523.1, NP_(—)001063601.1, ADB79567.1, AAL77443.1, AAL77445.1, AAQ08223.1, AAL79361.1, CAA52070.1, AAA33020.1, CAA52069.1, XP_(—)001785304.1, CAC39106.1, XP_(—)002992591.1, XP_(—)002968049.1, XP_(—)001770737.1, XP_(—)001752563.1, AAG43859.1, XP_(—)002978911.1, XP_(—)002977790.1, ACB29661.1, XP_(—)002314829.1, XP_(—)002991471.1, EAZ45287.1, XP_(—)002986974.1, EEC73687.1, XP_(—)002312421.1, ACJ84621.1, NP_(—)001150707.1, AAD28187.1, XP_(—)001759159.1, XP_(—)001757193.1, XP_(—)002322077.1, ABE01139.1, XP_(—)002447294.1, AAX54515.1, AAD33870.1, in particular AAC72881.1, ABB71579.1, CAC19934.1, AAC49180.1 (encoded by SEQ ID No. 10), AAC49783.1, AAC49179.1, CAB60830.1, ABB71581.1, AAC49269.1, CAC19933.1, CAA54060.1, AAC72882.1, Q39513.1, AAC49784.1, AAC72883.1, Q41635.1, AAC49001.1, and proteins with a polypeptide sequence wherein up to 60%, preferably up to 25%, particularly preferably up to 15%, in particular up to 10, 9, 8, 7, 6, 5, 4, 3, 2 or 1% of the amino acid residues compared to the aforementioned reference sequences are modified by deletion, insertion, substitution or a combination thereof and which still possess at least 50%, preferably 65%, particularly preferably 80%, in particular more than 90% of the activity of the protein with the corresponding, aforementioned reference sequence, wherein 100% activity of the reference protein is understood to mean the increasing of the activity of the cells used as a biocatalyst, i.e. the quantity of substance converted per unit time based on the cell quantity used (units per gram cell dry weight [U/g CDW]) in comparison to the activity of the biocatalyst in the absence of the reference protein, wherein the activity in this connection and in connection with the determination of the activity of the enzyme E_(i) in general is understood to mean in particular the hydrolysis of dodecanoyl-ACP thioesters.

Microorganisms preferred according to the invention are those which are obtained when the microorganisms listed below having a first genetic modification in the sense of the invention are used as the starting point, in that they are provided with the second genetic modification and optionally at least one further genetic modification in the sense of the invention.

WO2010063031 A2 describes, particularly in paragraphs [0007] to [0008], [0092] to [0100], [0135] to [0136], [0181] to [0186] and [0204] to [0213] and practical examples 4 to 8, microorganisms preferably used according to the invention which have a first genetic modification, so that compared to their wild type they are capable of forming more microbial oil from at least one simple carbon source. The document also describes enzymes E_(i) preferred according to the invention and the sequences thereof, particularly in paragraphs [0012] to [0013], [0155], [0160] to [0163], [0185] to [0190] and [0197] to [0199], FIG. 12, practical examples 4 to 8 and table 3.

WO2010063032 A2 describes, particularly in paragraphs [0007] to [0008], [0092] to [0100], to [0136], [0181] to [0186] and [0204] to [0213], and practical examples 4 to 8, microorganisms preferably used according to the invention which have a first genetic modification, so that compared to their wild type they are capable of forming more microbial oil from at least one simple carbon source. The document also describes enzymes E_(i) preferred according to the invention and the sequences thereof, particularly in paragraphs [0012] to [0013], [0155], [0160] to [0163], [0185] to [0190] and [0197] to [0199], FIG. 12, practical examples 4 to 8 and table 3.

WO2011003034 A2 describes, particularly on page 3, second paragraph to page 7, first paragraph, page 20, second paragraph, to page 22, second paragraph, and on page 156 to page 166, fifth paragraph, and in claims 1 to 100, microorganisms preferably used according to the invention which have a first genetic modification, so that compared to their wild type they are capable of forming more fatty acids and fatty acid derivatives, in particular adipic acid, from at least one simple carbon source. The document also describes enzymes E_(i) preferred according to the invention and the sequences thereof particularly on page 35, third paragraph, and page 36, first paragraph.

WO2011008565 A1 describes, particularly in paragraphs [0018] to [0024] and [0086] to [0102] and practical examples 2, 4, 7, 9 and 10, microorganisms preferably used according to the invention which have a first genetic modification, so that compared to their wild type they are capable of forming more fatty acids and fatty acid derivatives, in particular fatty acids, fatty aldehydes, fatty alcohols, alkanes and fatty acid ester, from at least one simple carbon source. The document also describes enzymes E_(i) preferred according to the invention and the sequences thereof, particularly in paragraphs [0009] to [0018] and [0073] to [0082], FIGS. 1 to 3 and 7, table 4, practical examples 1 to 10 and claims 1 to 5 and 11 to 13.

WO2009076559 A1 describes, particularly in paragraphs [0013] to [0051] and [0064] to [00111] and claims 1 to 10, microorganisms preferably used according to the invention which have a first genetic modification, so that compared to their wild type they are capable of forming more fatty acids and fatty acid derivatives, in particular fatty acids, fatty alcohols, alkanes or alkenes, from at least one simple carbon source. The document also describes enzymes E_(i) preferred according to the invention and the sequences thereof, particularly in table 1, paragraphs [0021], to [0030] and [0064] to [00111] and FIG. 6.

WO2010017245 A1 describes, particularly in paragraphs [0011] to [0015] and [00114] to [00134], practical example 3 and claims 1 to 2 and 9 to 11, microorganisms preferably used according to the invention which have a first genetic modification, so that compared to their wild type they are capable of forming more fatty acids and fatty acid derivatives from at least one simple carbon source. The document also describes enzymes E_(i) preferred according to the invention and the sequences thereof, particularly in tables 1, 2 and 3, paragraphs [0080] to and claims 3 to 8.

WO2010127318 A2 describes, particularly on pages 1 to 9 and 11 to 16, practical examples 1, 2 and 4, FIGS. 1A to 1E and claims 23 to 43, 62 to 79 and 101 to 120, microorganisms preferably used according to the invention which have a first genetic modification, so that compared to their wild type they are capable of forming more fatty acids and fatty acid derivatives, in particular biodiesel equivalents and other fatty acid derivatives, above all fatty acid ethyl esters, fatty acid esters, wax esters, fatty alcohols and fatty aldehydes, from at least one simple carbon source. The document also describes enzymes E_(i) preferred according to the invention and the sequences thereof, particularly on pages 17 and 19 to 23.

WO2008100251 A1 describes, particularly on pages 4 to 7 and 45 to 46, FIGS. 1A to 1E and claims 9 to 13, microorganisms preferably used according to the invention which have a first genetic modification, so that compared to their wild type they are capable of forming more fatty acids and fatty acid derivatives, in particular fatty acid esters, wax esters and fatty alcohols, from at least one simple carbon source. The document also describes enzymes E_(i) preferred according to the invention and the sequences thereof, particularly on pages 4 to 5 and 45 to 46.

WO2007136762 A2 describes, particularly on pages 2 to 4 and 17 to 18, table 7, FIGS. 2 to 4, practical examples 2 to 8 and claims 13 and 35, microorganisms preferably used according to the invention which have a first genetic modification, so that compared to their wild type they are capable of forming more fatty acids and fatty acid derivatives, in particular fatty acid esters, wax esters, hydrocarbons and fatty alcohols, from at least one simple carbon source. The document also describes enzymes E_(i) preferred according to the invention and the sequences thereof, particularly on pages 17 to 18, in tables 1, 7, 8 and 10 and FIG. 10.

WO2008113041 A2 describes, particularly on pages 35 to 41 and 64 to 67, FIG. 2, practical examples 6 and 10 and claims 7 and 36, microorganisms preferably used according to the invention which have a first genetic modification, so that compared to their wild type they are capable of forming more fatty acids and fatty acid derivatives, in particular fatty acid esters, wax esters, hydrocarbons, aliphatic ketones and fatty alcohols, from at least one simple carbon source. The document also describes enzymes E_(i) preferred according to the invention and the sequences thereof, particularly in FIG. 7 and practical examples 6 and 10.

WO2010126891 A1 describes, particularly in paragraphs [0034] to [0091], [0195] to [0222] and to [0250], FIGS. 3 to 5 and practical examples 1 to 5, microorganisms preferably used according to the invention which have a first genetic modification, so that compared to their wild type they are capable of forming more fatty acids and fatty acid derivatives, in particular fatty acid esters, wax esters and fatty alcohols, from at least one simple carbon source. The document also describes enzymes E_(i) preferred according to the invention and the sequences thereof, particularly in paragraphs [0245] to [0250], table 1 and practical examples 1 to 5.

WO2010118410 A1 describes, particularly in paragraphs [0022] to [0043], [0158] to [0197], FIGS. 1 to 4, practical examples 3 and 5 to 8 and claims 1 to 53 and 82 to 100, microorganisms preferably used according to the invention which have a first genetic modification, so that compared to their wild type they are capable of forming more fatty acids and fatty acid derivatives, in particular fatty acid esters and wax esters, from at least one simple carbon source. The document also describes enzymes E_(i) preferred according to the invention and the sequences thereof, particularly in paragraphs [0158] to [0197], table 1, FIGS. 3 and 4 and practical examples 3 and 5 to 8.

WO2010118409 A1 describes, particularly in paragraphs [0134] to [0154], FIGS. 1 to 3 and 6 and practical example 3, microorganisms preferably used according to the invention which have a first genetic modification, so that compared to their wild type they are capable of forming more fatty acids and fatty acid derivatives, in particular fatty acid esters and wax esters, from at least one simple carbon source. The document also describes enzymes E_(i) preferred according to the invention and the sequences thereof, particularly in paragraphs [0134] to [0154], FIGS. 3 and 6 and practical example 3.

WO2010075483 A2 describes, particularly in paragraphs [0061] to [0090], and [0287] to [0367], FIGS. 1, 4 and 5, practical examples 1 to 38 and claims 18 to 26, microorganisms preferably used according to the invention which have a first genetic modification, so that compared to their wild type they are capable of forming more fatty acids and fatty acid derivatives, in particular fatty acids, fatty acid methyl esters, fatty acid ethyl esters, fatty alcohols, fatty alkyl acetates, fatty aldehydes, fatty amines, fatty amides, fatty sulphates, fatty ethers, ketones, alkanes, internal and terminal olefins, dicarboxylic acids, α,ω-dicarboxylic acids and α,ω-diols, from at least one simple carbon source. The document also describes enzymes E_(i) preferred according to the invention and the sequences thereof, particularly in paragraphs [0012] to [0060], tables 7, 17, 26 and 27, FIGS. 1, 44 to 47 and 55 to 59, practical examples 1 to 38 and claims 1 to 17.

WO2010062480 A2 describes, particularly in paragraphs [0022] to [0174] and [0296] to [0330], practical examples 3 and 5 to 8 and claims 17 and 24, microorganisms preferably used according to the invention which have a first genetic modification, so that compared to their wild type they are capable of forming more fatty acids and fatty acid derivatives, in particular fatty alcohols, from at least one simple carbon source. The document also describes enzymes E_(i) preferred according to the invention and the sequences thereof, particularly in paragraphs [0022] to [0174], table 1, and practical examples 3 and 5 to 8.

WO2010042664 A2 describes, particularly in paragraphs [0022] to [0143] and [0241] to [0275], practical example 2 and claims 3 and 9, microorganisms preferably used according to the invention which have a first genetic modification, so that compared to their wild type they are capable of forming more fatty acids and fatty acid derivatives, in particular fatty aldehydes, from at least one simple carbon source. The document also describes enzymes E_(i) preferred according to the invention and the sequences, particularly in table 1, FIG. 5 and practical example 2.

WO2011008535 A1 describes, particularly in paragraphs [0024] to [0032], and [0138] to [0158] and FIG. 13, microorganisms preferably used according to the invention which have a first genetic modification, so that compared to their wild type they are capable of forming more fatty acids and fatty acid derivatives, in particular carboxylic acids, hydroxycarboxylic acids and lactones thereof, from at least one simple carbon source.

WO2010022090 A1 describes, particularly in paragraphs [0022] to [0143] and [0238] to [0275], FIGS. 3 to 5, practical example 2 and claims 5, 15, 16 and 36, microorganisms preferably used according to the invention which have a first genetic modification, so that compared to their wild type they are capable of forming more fatty acids and fatty acid derivatives, in particular fatty acid esters and wax esters, from at least one simple carbon source. The document also describes enzymes E_(i) preferred according to the invention and the sequences thereof, particularly in table 1, FIG. 6 and practical example 2.

WO2009140695 A1 describes, particularly in paragraphs [0214] to [0248] and practical examples 22 to 24, microorganisms preferably used according to the invention which have a first genetic modification, so that compared to their wild type they are capable of forming more fatty acids and fatty acid derivatives, in particular hydrocarbons, from at least one simple carbon source. The document also describes enzymes E_(i) preferred according to the invention and the sequences thereof in particular in table 1, FIG. 40 and practical examples 22 to 24.

WO2010021711 A1 describes, particularly in paragraphs [0009] to [0020] and [0257] to [0317], FIGS. 3 to 5 and 19, practical examples 2 to 24 and claims 4, 5 and 30, microorganisms preferably used according to the invention which have a first genetic modification, so that compared to their wild type they are capable of forming more fatty acids and fatty acid derivatives, in particular fatty acid esters and wax esters, from at least one simple carbon source. The document also describes enzymes E_(i) preferred according to the invention and the sequences thereof, in particular in table 3, FIG. 6 and practical examples 2 to 24.

WO2009085278 A1 describes, particularly in paragraphs [0188] to [0192] and FIG. 10, microorganisms preferably used according to the invention which have a first genetic modification, so that compared to their wild type they are capable of forming more fatty acids and fatty acid derivatives, in particular olefins, from at least one simple carbon source. The document also describes enzymes E_(i) preferred according to the invention and the sequences thereof, particularly in table 1 and FIG. 10.

WO2011019858 A1 describes, particularly in paragraphs [0023], [0064] to [0074] and [0091] to [0099], practical examples 1 to 13, FIG. 1 and claim 8, microorganisms preferably used according to the invention which have a first genetic modification, so that compared to their wild type they are capable of forming more fatty acids and fatty acid derivatives, in particular fatty alcohols, from at least one simple carbon source. The document also describes preferred enzymes E_(i) according to the invention and the sequences thereof, particularly in paragraphs [0085] to [0090], practical examples 1 to 13 and table 1.

WO2009009391 A2 describes, particularly in paragraphs [0010] to [0019] and [0191] to [0299], FIGS. 3 to 5, practical examples 2, 4 to 6, 9 to 14, 17 and 19 and claims 16, 39, 44 and 55 to 59, microorganisms preferably used according to the invention which have a first genetic modification, so that compared to their wild type they are capable of forming more fatty acids and fatty acid derivatives, in particular fatty acid esters, wax esters and fatty alcohols, from at least one simple carbon source. The document also describes enzymes E_(i) preferred according to the invention and the sequences thereof, particularly in paragraphs [0010] to [0019] and [0191] to [0299], FIG. 9 and practical examples 2, 4 to 6, 9 to 14, 17 and 19.

WO2008151149 A2 describes, particularly in paragraphs [0009], [0015] to [0033], [0053], [0071], [0174] to [0191], [0274] and [0396], claims 53 to 114, 188 to 206 and 344 to 355 and tables 1 to 3, microorganisms preferably used according to the invention which have a first genetic modification, so that compared to their wild type they are capable of forming more microbial oil from at least one simple carbon source. The document also describes enzymes E_(i) preferred according to the invention and the sequences thereof, particularly in table 5.

WO2008147781 A2 describes, particularly in paragraphs [0147] to [0156], practical examples 1 to 3, 8, 9 and 14 and claims 65 to 71, microorganisms preferably used according to the invention which have a first genetic modification, so that compared to their wild type they are capable of forming more fatty acids and fatty acid derivatives, in particular hydrocarbons, olefins and aliphatic ketones, from at least one simple carbon source. The document also describes enzymes E_(i) preferred according to the invention and the sequences thereof in particular in practical examples 1 to 3, 8, 9 and 14.

WO2008119082 A2 describes, particularly on pages 3 to 5, 8 to 10 and 40 to 77, in FIGS. 4 and 5, practical examples 2 to 5 and 8 to 18 and claims 3 to 39 and 152 to 153, microorganisms preferably used according to the invention which have a first genetic modification, so that compared to their wild type they are capable of forming more fatty acids and fatty acid derivatives, in particular fatty acid esters, wax esters, triglycerides, biodiesel, gasoline, aviation fuel and fatty alcohols from at least one simple carbon source. The document also describes enzymes E_(i) preferred according to the invention and the sequences thereof, particularly in table 1, FIG. 1, practical examples 2 to 5 and 8 to 18 and claims 124 to 134 and 138 to 141.

WO2010135624 A2 describes, particularly in paragraphs [0067] to [0083], and [0095] to [0098], microorganisms preferably used according to the invention which have a first genetic modification, so that compared to their wild type they are capable of forming more fatty acids and fatty acid derivatives, in particular fatty alcohols, from at least one simple carbon source. The document also describes enzymes E_(i) preferred according to the invention and the sequences thereof, particularly in paragraphs [0067] to [0083] and [0095] to [0098]. Zheng Z, Gong Q, Liu T, Deng Y, Chen J C and Chen G Q. (Thioesterase II of Escherichia coli plays an important role in 3-hydroxydecanoic acid production. Appl Environ Microbiol. 2004. 70(7):3807-13) describe, particularly on pages 3808 to 3810 and 3012 and table 1, 3 and 4, microorganisms preferably used according to the invention which have a first genetic modification, so that compared to their wild type they are capable of forming more fatty acids and fatty acid derivatives, in particular fatty acid esters, wax esters and fatty alcohols, from at least one simple carbon source. The document also describes enzymes E_(i) preferred according to the invention and the sequences thereof, particularly on pages 3807 and in table 2. Steen E J, Kang Y, Bokinsky G, Hu Z, Schirmer A, McClure A, Del Cardayre S B and Keasling J D (Microbial production of fatty acid-derived fuels and chemicals from plant biomass. Nature. 2010. 463(7280):559-62) describe, particularly on p. 559, third paragraph, to p. 559, first paragraph, microorganisms preferably used according to the invention which have a first genetic modification, so that compared to their wild type they are capable of forming more fatty acids and fatty acid derivatives, in particular fatty acids and fatty acid esters, from at least one simple carbon source. The document also describes enzymes E_(i) preferred according to the invention and the sequences thereof, in particular in supplementary table 1.

Lennen R M, Braden D J, West R A, Dumesic J A and Pfleger B F (A process for microbial hydrocarbon synthesis: Overproduction of fatty acids in Escherichia coli and catalytic conversion to alkanes. Biotechnol Bioeng. 2010. 106(2):193-202) describe, particularly on p. 193, first paragraph, p. 194, first and second paragraph, p. 195, second paragraph to p. 197, second paragraph, p. 198, second paragraph to p. 199, third paragraph, microorganisms preferably used according to the invention which have a first genetic modification, so that compared to their wild type they are capable of forming more fatty acids and fatty acid derivatives, in particular fatty acids and fatty acid esters, from at least one simple carbon source. The document also describes enzymes E_(i) preferred according to the invention and the sequences thereof, in particular on p. 193, first paragraph, p. 194, first and second paragraph, p. 196, second paragraph, and in the supplementary material.

Liu T, Vora H and Khosla C. (Quantitative analysis and engineering of fatty acid biosynthesis in E. coli. Metab Eng. 2010 July; 12(4):378-86.) describe, particularly in sections 2.2, and 3.1 and in table 1 and 2, microorganisms preferably used according to the invention which have a first genetic modification, so that compared to their wild type they are capable of forming more fatty acids and fatty acid derivatives, in particular fatty acids and fatty acid esters, from at least one simple carbon source. The document also describes enzymes E₁ preferred according to the invention and the sequences thereof, in particular in table 1.

Yuan L, Voelker T A and Hawkins D J. (Modification of the substrate specificity of an acyl-acyl carrier protein thioesterase by protein engineering. Proc Natl Acad Sci USA. 1995 Nov. 7; 92(23):10639-43) describe, particularly on p. 10641, fourth paragraph, and in FIG. 2 and table 1, microorganisms preferably used according to the invention which have a first genetic modification, so that compared to their wild type they are capable of forming more fatty acids and fatty acid derivatives, in particular fatty acids and fatty acid esters, from at least one simple carbon source. The document also describes enzymes E_(i) preferred according to the invention and the sequences thereof, in particular on p. 10639 first paragraph, p. 10640, second, third and last paragraph, p. 10641, second and third paragraph, and in FIG. 1 and table 1 and 2.

Liu X, Vora H and Khosla C. (Overproduction of free fatty acids in E. coli: implications for biodiesel production. Metab Eng. 2008. 10(6):333-9.) describe, particularly on p. 334, second paragraph, paragraphs 2.2, 2.3 and 3 (first to fourth paragraph) and in table 1, microorganisms preferably used according to the invention which have a first genetic modification, so that compared to their wild type they are capable of forming more fatty acids and fatty acid derivatives, in particular fatty acids and fatty acid esters, from at least one simple carbon source. The document also describes enzymes E_(i) preferred according to the invention and the sequences thereof, in particular in paragraph 2.2.

Liu X, Sheng J and Curtiss IIII R. (Fatty acid production in genetically modified cyanobacteria. Proc Natl Acad Sci USA. 2011. 108(17):6899-904) describe, particularly on p. 6899, fourth and last paragraph, p. 6900, first to penultimate paragraph, and in table S1 of the “Supporting Information”, microorganisms preferably used according to the invention which have a first genetic modification, so that compared to their wild type they are capable of forming more fatty acids and fatty acid derivatives, in particular fatty acids and fatty acid esters, from at least one simple carbon source. The document also describes enzymes E_(i) preferred according to the invention and the sequences thereof, in particular on p. 6899, sixth and last paragraph.

Specific Enzymes E_(ii)

Microorganisms preferred according to the invention are those which are obtained when the microorganisms listed below having a first genetic modification in the sense of the invention are used as the starting point, in that they are provided with the second genetic modification and optionally at least one further genetic modification in the sense of the invention.

Steen E J, Kang Y, Bokinsky G, Hu Z, Schirmer A, McClure A, Del Cardayre S B and Keasling J D (Microbial production of fatty-acid-derived fuels and chemicals from plant biomass. Nature. 2010. 463(7280):559-62) describe, particularly on p. 559, third paragraph, to p. 559, first paragraph, microorganisms preferably used according to the invention which have a first genetic modification, so that compared to their wild type they are capable of forming more carboxylic acids and carboxylate esters, in particular fatty acids and fatty acid esters, from at least one simple carbon source. The document also describes enzymes E_(ii) preferred according to the invention and the sequences thereof, in particular in supplementary table 1.

Lennen R M, Braden D J, West R A, Dumesic J A and Pfleger B F (A process for microbial hydrocarbon synthesis: Overproduction of fatty acids in Escherichia coli and catalytic conversion to alkanes. Biotechnol Bioeng. 2010. 106(2):193-202) describe, particularly on p. 193, first paragraph, p. 194, first and second paragraph, p. 195, second paragraph to p. 197, second paragraph, p. 198, second paragraph to p. 199, third paragraph, microorganisms preferably used according to the invention which have a first genetic modification, so that compared to their wild type they are capable of forming more carboxylic acids and carboxylate esters, in particular fatty acids and fatty acid esters, from at least one simple carbon source. The document also describes enzymes E_(ii) preferred according to the invention and the sequences thereof, in particular on p. 193, first paragraph, p. 194, first and second paragraph, p. 196, second paragraph, and in the supplementary material.

Liu T, Vora H and Khosla C. (Quantitative analysis and engineering of fatty acid biosynthesis in E. coli. Metab Eng. 2010 July; 12(4):378-86.) describe, particularly in sections 2.2, and 3.1 and in table 1 and 2, microorganisms preferably used according to the invention which have a first genetic modification, so that compared to their wild type they are capable of forming more carboxylic acids and carboxylate esters, in particular fatty acids and fatty acid esters, from at least one simple carbon source. The document also describes enzymes E_(ii) preferred according to the invention and the sequences thereof, in particular in table 1.

Yuan L, Voelker T A and Hawkins D J. (Modification of the substrate specificity of an acyl-acyl carrier protein thioesterase by protein engineering. Proc Natl Acad Sci USA. 1995 Nov. 7; 92(23):10639-43) describe, particularly on p. 10641, fourth paragraph, and in FIG. 2 and table 1 microorganisms preferably used according to the invention which have a first genetic modification, so that compared to their wild type they are capable of forming more carboxylic acids and carboxylate esters, in particular fatty acids and fatty acid esters, from at least one simple carbon source. The document also describes enzymes E_(ii) preferred according to the invention and the sequences thereof, in particular on p. 10639 first paragraph, p. 10640, second, third and last paragraph, p. 10641, second and third paragraph, and in FIG. 1 and table 1 and 2.

Liu X, Vora H and Khosla C. (Overproduction of free fatty acids in E. coli: implications for biodiesel production. Metab Eng. 2008. 10(6):333-9.) describe, particularly on p. 334, second paragraph, paragraphs 2.2, 2.3 and 3 (first to fourth paragraph) and in table 1, microorganisms preferably used according to the invention which have a first genetic modification, so that compared to their wild type they are capable of forming more carboxylic acids and carboxylate esters, in particular fatty acids and fatty acid esters, from at least one simple carbon source. The document also describes enzymes E_(d) preferred according to the invention and the sequences thereof, in particular in paragraph 2.2.

Liu X, Sheng J and Curtiss IIII R. (Fatty acid production in genetically modified cyanobacteria. Proc Natl Acad Sci USA. 2011. 108(17):6899-904) describe, particularly on p. 6899, fourth and last paragraph, p. 6900, first to penultimate paragraph, and in table S1 of the “Supporting Information”, microorganisms preferably used according to the invention which have a first genetic modification, so that compared to their wild type they are capable of forming more carboxylic acids and carboxylate esters, in particular fatty acids and fatty acid esters, from at least one simple carbon source. The document also describes enzymes E_(i) preferred according to the invention and the sequences thereof, in particular on p. 6899, sixth and last paragraph.

Specific Enzymes E_(iii)

Microorganisms preferred according to the invention are those which are obtained when the microorganisms listed below having a first genetic modification in the sense of the invention are used as the starting point, in that they are provided with the second genetic modification and optionally at least one further genetic modification in the sense of the invention.

WO2009121066 A1 describes, particularly in claims 8 to 14, microorganisms preferably used according to the invention which have a first genetic modification, so that compared to their wild type they are capable of forming more fatty acids and fatty acid derivatives, in particular dicarboxylic acids, from at least one simple carbon source. The document also describes enzymes E_(iii) preferred according to the invention and the sequences thereof, particularly in paragraphs [00026] to [0054], practical examples 1 to 6, FIGS. 4 to 10 and claims 1 to 7.

WO2009134899 A1 describes, particularly in paragraphs [0079] to [0082], practical example 1 and claim 20, microorganisms preferably used according to the invention which have a first genetic modification, so that compared to their wild type they are capable of forming more fatty acids and fatty acid derivatives, in particular carboxylic acids, hydroxycarboxylic acids and lactones thereof, from at least one simple carbon source. The document also describes enzymes E_(iii) preferred according to the invention and the sequences thereof, particularly in paragraphs [0009] to [0010] and [0044] to [0078], practical example 1, FIGS. 1 and 5 to 8 and claims 15 to 17 and 19.

Specific Enzymes E_(iv)

In cells preferred according to the invention, the enzyme is one which comprises sequences selected from:

AAS90071.1, XP_(—)002379948.1, AAS90024.1, XP_(—)001821514.2, BAE59512.1, AAL99898.1, AAS90001.1, AAS90049.1, XP_(—)001911518.1, ACH72901.1, XP_(—)681084.1, AAC49198.1, EFW18013.1, XP_(—)003070494.1, XP_(—)001241401.1, XP_(—)002384449.1, XP_(—)001827206.1, XP_(—)002836001.1, XP_(—)001393196.1, XP_(—)660984.1, XP_(—)001395284.1, XP_(—)002148677.1, XP_(—)001827151.2, BAE66018.1, XP_(—)001217254.1, CAK40139.1, XP_(—)001393516.2, XP_(—)002477829.1, XP_(—)002146311.1, XP_(—)002340042.1, XP_(—)002544942.1, CBF87553.1, XP_(—)002149766.1, 2UV8_A, XP_(—)682676.1, CBX98966.1, XP_(—)002560069.1, XP_(—)001273102.1, P15368.1, XP_(—)001273530.1, CBX99714.1, AAB41493.1, XP_(—)001823764.1, XP_(—)001388458.1, XP_(—)748738.1, EDP53207.1, XP_(—)001259179.1, XP_(—)001825741.2, BAE64608.1, XP_(—)001213437.1, XP_(—)002377327.1, XP_(—)002152724.1, EFZ04065.1, XP_(—)001792784.1, EGP89632.1, XP_(—)001407660.1, EFQ31023.1, XP_(—)003040066.1, 2UV9_A, XP_(—)002486436.1, XP_(—)001585982.1, EFY87204.1, XP_(—)002620504.1, XP_(—)003295647.1, EEQ86108.1, XP_(—)001938586.1, XP_(—)001547465.1, XP_(—)001906653.1, XP_(—)001402457.2, CAK40502.1, XP_(—)002568116.1, XP_(—)003230922.1, XP_(—)001647236.1, XP_(—)385497.1, EGD94294.1, EGE05134.1, XP_(—)002849847.1, XP_(—)003015737.1, EFX06093.1, XP_(—)003019052.1, EEH03423.1, XP_(—)001942351.1, EGC45478.1, XP_(—)002556020.1, XP_(—)003011025.1, CAY86729.1, EDN60916.1, EGA84463.1, EGA56454.1, EEU05652.1, NP_(—)015093.1, XP_(—)003231214.1, XP_(—)445956.1, EGA60201.1, XP_(—)003349949.1, XP_(—)003070417.1, XP_(—)001241314.1, EGR48038.1, XP_(—)002615278.1, EFW15042.1, EGO59647.1, XP_(—)452914.1, XP_(—)962466.1, XP_(—)001537327.1, XP_(—)002796517.1, XP_(—)003305240.1, XP_(—)002543037.1, XP_(—)002499262.1, NP_(—)985412.2, XP_(—)003019770.1, EFW96269.1, XP_(—)002843350.1, EEH43965.1, XP_(—)457388.1, XP_(—)001799391.1, EEH21370.1, BAD08376.1, XP_(—)001486434.1, BAF79876.1, EFY90998.1, XP_(—)001939431.1, EER44845.1, EFZ02060.1, XP_(—)001386834.2, XP_(—)501096.1, XP_(—)003299758.1, XP_(—)002419391.1, XP_(—)002490414.1, ACZ66251.1, XP_(—)002548204.1, P43098.1, XP_(—)002176039.1, XP_(—)002479407.1, EEQ44526.1, AAA34601.1, XP_(—)001791764.1, XP_(—)003009337.1, BAA11913.1, NP_(—)593823.1, BAB62031.1, BAB62032.1, BAB62030.1, 2 PFF_A, XP_(—)380212.1, ADN94478.1, EGF83443.1, XP_(—)681149.1, EGG00662.1, ADN94479.1, ABC94883.1, XP_(—)571099.1, EFY94095.1, EFW39589.1, XP_(—)003194430.1, XP_(—)003031600.1, XP_(—)001836417.1, XP_(—)001880844.1, XP_(—)762607.1, EGN98830.1, EGO24420.1, ACD87451.1, XP_(—)003328630.1, XP_(—)002997955.1, CCA25392.1, XP_(—)002901724.1, EFY86381.1, XP_(—)002901728.1, ADN97213.1, XP_(—)759118.1, XP_(—)003325251.1, XP_(—)003169619.1, XP_(—)002555446.1, ABJ98780.1, XP_(—)723161.1, EDZ68993.1, XP_(—)001526334.1, XP_(—)001223165.1, YP_(—)889015.1, AAO43178.1, YP_(—)001702252.1, XP_(—)003026305.1, YP_(—)003659808.1, ZP_(—)08155637.1, ZP_(—)04749666.1, ZP_(—)08022190.1, YP_(—)004007770.1, YP_(—)954908.1, YP_(—)004522637.1, YP_(—)640811.1, ZP_(—)04448562.1, NP_(—)301868.1, ZP_(—)06851996.1, YP_(—)003273140.1, YP_(—)001071929.1, YP_(—)001133797.1, YP_(—)004076455.1, YP_(—)701403.1, ZP_(—)03324816.1, YP_(—)002778327.1, ZP_(—)02028077.1, YP_(—)909119.1, YP_(—)880884.1, YP_(—)002767320.1, NP_(—)961266.1, ZP_(—)07457010.1, ZP_(—)08206945.1, ZP_(—)02917151.1, ZP_(—)04387794.1, YP_(—)003359863.1, EGO39886.1, ABE96385.1, ZP_(—)05228143.1, ZP_(—)06522069.1, EGL13180.1, ZP_(—)06976698.1, YP_(—)001852225.1, ZP_(—)06596502.1, YP_(—)907384.1, ZP_(—)06518033.1, AEF27803.1, YP_(—)003374392.1, ZP_(—)07485570.1, NP_(—)217040.1, ZP_(—)03742148.1, NP_(—)856198.1, YP_(—)004724192.1, NP_(—)337093.1, AEJ51135.1, ZP_(—)05765008.1, YP_(—)004745991.1, AEJ47516.1, ZP_(—)06927266.1, ZP_(—)03646962.1, AEF31807.1, YP_(—)003939358.1, YP_(—)003971698.1, YP_(—)003986333.1, ZP_(—)05750911.1, ADD61451.1, ZP_(—)07942485.1, YP_(—)004209716.1, YP_(—)004221489.1, AEI96705.1, NP_(—)696693.1, AEG82252.1, YP_(—)004001156.1, ZP_(—)03976473.1, ZP_(—)04663991.1, ZP_(—)00121397.1, YP_(—)003662064.1, YP_(—)003646283.1, YP_(—)004630447.1, YP_(—)002323720.1, YP_(—)002835610.1, YP_(—)117466.1, ZP_(—)02963252.1, ADC85342.1, NP_(—)940183.1, NP_(—)739002.1, ZP_(—)06755645.1, ADL21513.1, YP_(—)003784047.1, ADL11108.1, ZP_(—)06608499.1, ZP_(—)07967121.1, ZP_(—)05966223.1, ZP_(—)08682531.1, ZP_(—)03918327.1, ZP_(—)07879655.1, ZP_(—)03972703.1, ZP_(—)06162645.1, ZP_(—)06837277.1, ZP_(—)07990916.1, ZP_(—)03394081.1, CAA46024.1, YP_(—)004760934.1, ZP_(—)06751771.1, ZP_(—)03934033.1, NP_(—)601696.1, BAB99888.1, YP_(—)001139316.1, ZP_(—)03926457.1, NP_(—)737523.1, ZP_(—)02044858.1, ZP_(—)07404023.1, ZP_(—)03709883.1, XP_(—)002388648.1, ZP_(—)07402466.1, ZP_(—)03710807.1, ZP_(—)08294093.1, ZP_(—)08232611.1, XP_(—)682514.1, ZP_(—)06837028.1, YP_(—)001137826.1, CAA61087.1, ZP_(—)06043461.1, YP_(—)002833817.1, YP_(—)225128.1, NP_(—)600065.1, ABU23831.1, ZP_(—)07716892.1, ZP_(—)03935133.1, ZP_(—)02549600.1, ZP_(—)05215994.1, YP_(—)004494858.1, XP_(—)001526333.1, AAS90085.1, XP_(—)002379947.1, AAS90025.1, XP_(—)001821515.1, AAL99899.1, AAS90002.1, AAS90050.1, XP_(—)001911517.1, ACH72900.1, XP_(—)681083.1, AAC49199.1, XP_(—)003070495.1, XP_(—)001241402.1, EFW18012.1, CBX98970.1, EEH03422.1, EEQ86107.1, EGC45479.1, XP_(—)002620503.1, XP_(—)001537328.1, XP_(—)002796516.1, 2UVA_G, EEH43966.1, DAA05950.1, EGR47893.1, XP_(—)003070418.1, XP_(—)001241316.1, XP_(—)001827193.1, XP_(—)002384436.1, XP_(—)682677.1, XP_(—)002486435.1, EGP88608.1, EDP53206.1, XP_(—)001259180.1, EEH21369.1, XP_(—)002543038.1, XP_(—)748739.1, XP_(—)003015735.1, EGE05135.1, XP_(—)002152723.1, XP_(—)002560068.1, XP_(—)001273529.1, XP_(—)003230923.1, EFX05327.1, XP_(—)003019051.1, XP_(—)001585981.1, XP_(—)361644.2, XP_(—)001223166.1, XP_(—)003349948.1, XP_(—)002380737.1, AAB41494.1, XP_(—)001823765.1, XP_(—)962465.1, EGO59648.1, XP_(—)001906652.1, XP_(—)003039864.1, XP_(—)001213436.1, XP_(—)385498.1, XP_(—)003295646.1, EFQ31022.1, XP_(—)002849848.1, XP_(—)002148679.1, CBX99715.1, XP_(—)002149767.1, EFY87205.1, EFZ04064.1, XP_(—)002340041.1, EGD94295.1, XP_(—)001938587.1, CAK45758.1, XP_(—)001792785.1, XP_(—)001393189.2, XP_(—)003169620.1, XP_(—)001547461.1, XP_(—)001217253.1, XP_(—)001939430.1, BAA92930.1, Q92215.1, EDK38075.2, EFW97345.1, XP_(—)002495511.1, XP_(—)451653.1, XP_(—)500912.1, CAA42211.1, XP_(—)001486502.1, XP_(—)002477835.1, XP_(—)445436.1, NP_(—)594370.1, XP_(—)001827152.2, BAE66019.1, BAA36384.1, BAB62141.1, XP_(—)003299759.1, XP_(—)002553365.1, XP_(—)002489642.1, 2UV8_G, XP_(—)457311.1, CAY80909.1, XP_(—)001395285.1, EGA61562.1, EDN60099.1, EDV12927.1, NP_(—)012739.1, XP_(—)002616181.1, XP_(—)002420328.1, XP_(—)001524822.1, XP_(—)002550943.1, XP_(—)001386364.2, NP_(—)984945.2, 227846, AAB59310.1, XP_(—)001646561.1, XP_(—)716877.1, XP_(—)001836417.1, XP_(—)002146312.1, P34731.1, EGO24420.1, XP_(—)002544941.1, EFZ02054.1, XP_(—)002175228.1, XP_(—)001393490.2, XP_(—)003031600.1, XP_(—)002479408.1, XP_(—)002568119.1, XP_(—)001825735.2, XP_(—)002377320.1, EGN98830.1, ACD87451.1, XP_(—)001880844.1, XP_(—)571100.1, ABC94882.1, XP_(—)775164.1, BAE64602.1, EFY90992.1, XP_(—)003194424.1, XP_(—)001273103.1, XP_(—)681142.1, XP_(—)003011020.1, AAA34602.1, XP_(—)003231209.1, XP_(—)003019765.1, ADN94478.1, EEQ46070.1, XP_(—)001799393.1, CAK40504.1, AAM75418.1, ADN94479.1, XP_(—)002843356.1, CAA27616.1, XP_(—)380213.1, ADN97213.1, XP_(—)759118.1, XP_(—)762607.1, CAK49094.1, EER44843.1, XP_(—)003009335.1, XP_(—)002997955.1, XP_(—)002901724.1, CCA25392.1, CAK36856.1, XP_(—)001388457.2, ABO37974.1, ABJ98780.1, XP_(—)660985.1, EDZ71063.1, XP_(—)001402459.2, XP_(—)001791765.1, XP_(—)003324647.1, EGG10429.1, EFW15039.1, XP_(—)002384390.1, XP_(—)003031976.1, EDZ71062.1, EFW39589.1, ACZ80683.1, XP_(—)002901728.1, XP_(—)003328630.1, XP_(—)681125.1, XP_(—)003325251.1, and proteins with a polypeptide sequence wherein up to 60%, preferably up to 25%, particularly preferably up to 15%, in particular up to 10, 9, 8, 7, 6, 5, 4, 3, 2 or 1% of the amino acid residues compared to the aforementioned reference sequences are modified by deletion, insertion, substitution or a combination thereof and which still possess at least 50%, preferably 65%, particularly preferably 80%, in particular more than 90% of the activity of the protein with the corresponding, aforementioned reference sequence, wherein 100% activity of the reference protein is understood to mean the increasing of the activity of the cells used as a biocatalyst, i.e. the quantity of substance converted per unit time based on the cell quantity used (units per gram cell dry weight [U/g CDW]) in comparison to the activity of the biocatalyst in the absence of the reference protein, wherein the activity in this connection and in connection with the determination of the activity of the enzyme E_(iv) in general is understood to mean in particular the conversion to hexanoic acid from 2 molecules of malonyl-coenzyme A and one molecule of acetyl-coenzyme A.

Microorganisms preferred according to the invention are those which are obtained when the microorganisms listed below having a first genetic modification in the sense of the invention are used as the starting point, in that they are provided with the second genetic modification and optionally at least one further genetic modification in the sense of the invention.

WO2011003034 A2 describes, particularly on p. 2 to 3, p. 5 third paragraph, in practical examples 1 to 4, 7 to 9 and 12 to 14 and claims 1 to 100, microorganisms preferably used according to the invention which have a first genetic modification, so that compared to their wild type they are capable of forming more fatty acids and fatty acid derivatives, in particular hexanoic acid, from at least one simple carbon source. The document also describes enzymes E_(iv) preferred according to the invention and the sequences thereof, particularly on p. 5 and in practical example 3.

Hitchman T S, Schmidt E W, Trail F, Rarick M D, Linz J E and Townsend C A. (Hexanoate synthase, a specialized type I fatty acid synthase in aflatoxin B1 biosynthesis. Bioorg Chem. 2001. 29(5):293-307) describe, particularly on p. 296, penultimate paragraph, to p. 298, second paragraph, microorganisms preferably used according to the invention which have a first genetic modification, so that compared to their wild type they are capable of forming more fatty acids and fatty acid derivatives, in particular hexanoic acid, from at least one simple carbon source. The document also describes enzymes E_(iv) preferred according to the invention and the sequences thereof in in particular p. 299, fourth paragraph, to p. 302, first paragraph.

In connection with the first genetic modification, it can be beneficial instead of the enzyme E_(i) to use a combination of increasing the activity of an enzyme E_(ii) compared to that of the wild type paired with that of an enzyme E_(iib) which catalyses a reaction wherein a CoA thioester is converted into an ACP thioester.

Suitable enzymes E_(iib) are known as acyl-CoA (coenzyme A):ACP (acyl carrier protein) transacylases. Preferred enzymes E_(iib) are selected from

XP_(—)003402554.1, YP_(—)002908243.1, YP_(—)001778804.1, YP_(—)001670627.1, YP_(—)004703658.1, YP_(—)001747923.1, YP_(—)004348703.1, YP_(—)004352505.1, YP_(—)004379169.1, ADR61731.1, YP_(—)001269622.1, YP_(—)001186851.1, YP_(—)004659609.1, YP_(—)003519049.1, YP_(—)001811696.1, YP_(—)004616040.1, NP_(—)252697.1, NP_(—)252169.1, NP_(—)249421.1, ZP_(—)06456665.1, ZP_(—)01167071.1, ZP_(—)08557569.1, ZP_(—)08554397.1, YP_(—)001157914.1, YP_(—)004475334.1, EGM20156.1, BAK10182.1, YP_(—)347066.1, Q9KJH8.1, YP_(—)002987902.1, ZP_(—)03794633.1, ZP_(—)03627777.1, YP_(—)004434330.1, NP_(—)743567.1, ZP_(—)03456835.1, ZP_(—)07911512.1, ZP_(—)07264431.1, ZP_(—)02265387.2, ZP_(—)03456013.1, ZP_(—)07577798.1, ZP_(—)08429367.1, YP_(—)004055319.1, YP_(—)004053883.1, YP_(—)275219.1, YP_(—)276116.1, YP_(—)003882762.1, EGH97259.1, EGH95622.1, EGH90852.1, EGH85976.1, EGH81248.1, EGH79586.1, EGH79549.1, EGH73565.1, EGH66549.1, EGH64812.1, EGH58099.1, EGH54896.1, EGH50352.1, EGH43364.1, EGH41593.1, EGH29888.1, EGH29417.1, EGH22392.1, EGH22129.1, EGH11618.1, EGH10011.1, ZP_(—)04589662.1, CCA60711.1, YP_(—)003004716.1, BAK16630.1, YP_(—)003264146.1, YP_(—)371314.1, YP_(—)439272.1, NP_(—)762892.1, ADW02533.1, YP_(—)003291774.1, EGC99875.1, ZP_(—)08139631.1, YP_(—)003333890.1, EGC08366.1, YP_(—)080427.1, YP_(—)258557.1, YP_(—)001985016.1, YP_(—)002875182.1, YP_(—)002871082.1, YP_(—)237050.1, YP_(—)236199.1, NP_(—)794008.1, NP_(—)793082.1, YP_(—)609790.1, EFW81598.1, EFW79804.1, ZP_(—)07261632.1, ZP_(—)07229875.1, ZP_(—)06458504.1, ZP_(—)05640568.1, ZP_(—)03399268.1, ZP_(—)03398232.1, ZP_(—)08004496.1, ZP_(—)06876938.1, ZP_(—)03227482.1, ZP_(—)02511781.1, ZP_(—)02503964.1, ZP_(—)02477255.1, ZP_(—)02466678.1, ZP_(—)02465791.1, ZP_(—)02461688.1, ZP_(—)02417235.1, ZP_(—)02414413.1, ZP_(—)02408727.1, ZP_(—)02376540.1, ZP_(—)02358949.1, ZP_(—)07778021.1, ZP_(—)07774051.1, ZP_(—)07795409.1, ZP_(—)07089008.1, YP_(—)776393.1, ZP_(—)07684652.1, ZP_(—)06640022.1, ZP_(—)03054335.1, ZP_(—)02907621.1, ZP_(—)02891475.1, ZP_(—)01862226.1, ZP_(—)01769192.1, ZP_(—)01367441.1, ZP_(—)01366930.1, ZP_(—)01364106.1, ZP_(—)01312991.1, ZP_(—)01173135.1, ZP_(—)07005523.1, ZP_(—)04955702.1, ZP_(—)04943305.1, ZP_(—)04936014.1, ZP_(—)04932415.1, ZP_(—)04930223.1, ZP_(—)04905334.1, ZP_(—)04893870.1, ZP_(—)04893165.1, ZP_(—)04892059.1, ZP_(—)04884056.1, YP_(—)002438575.1, YP_(—)002234939.1, YP_(—)001488024.1, YP_(—)001346487.1, YP_(—)001350135.1, YP_(—)001347031.1, YP_(—)990329.1, YP_(—)860279.1, YP_(—)789111.1, YP_(—)792557.1, YP_(—)623139.1, YP_(—)175644.1, YP_(—)111362.1, YP_(—)110557.1, YP_(—)105231.1, NP_(—)937516.1, AAU44816.1, AAA25978.1, XP_(—)002721010.1, AAK81868.1, AAK71350.1, AAK71349.1, ZP_(—)06499968.1, ZP_(—)06498781.1, YP_(—)003472045.1, ACA03779.1, ABL84756.1, AAQ16175.1, AAT51302.1, AAT51199.1, ZP_(—)05639386.1, ACH70299.1, ACA60824.1, BAB32432.1, in particular AAK81868.1, NP_(—)743567.1, AAK71349.1, YP_(—)001269622.1, ADR61731.1, AAU44816.1, AAQ16175.1, YP_(—)001670627.1, ACH70299.1, Q9KJH8.1, YP_(—)004703658.1, ZP_(—)08139631.1, YP_(—)609790.1, YP_(—)001747923.1, YP_(—)258557.1, YP_(—)347066.1, YP_(—)002871082.1, YP_(—)004352505.1, ACA60824.1, ZP_(—)07774051.1, BAB32432.1, ZP_(—)05640568.1, EGH58099.1, EGH64812.1, EGH11618.1, ZP_(—)06456665.1, YP_(—)276116.1, EFW81598.1, EGH95622.1, EGH22129.1, NP_(—)794008.1, ZP_(—)03399268.1, ZP_(—)07264431.1, EGH73565.1, YP_(—)237050.1, ZP_(—)06498781.1, EGH29888.1, EGH79586.1, EGH50352.1, YP_(—)792557.1, YP_(—)001350135.1, ZP_(—)01364106.1, ZP_(—)04932415.1, NP_(—)249421.1, YP_(—)004379169.1, ACAO3779.1, YP_(—)001186851.1, YP_(—)004475334.1, ZP_(—)04589662.1, ZP_(—)03398232.1, EGH10011.1, ZP_(—)07229875.1, ZP_(—)05639386.1, EGH66549.1, YP_(—)275219.1, ZP_(—)07005523.1, EFW79804.1, ZP_(—)06458504.1, EGH85976.1, YP_(—)236199.1, EGH43364.1, ZP_(—)07261632.1, ZP_(—)06499968.1, EGH29417.1, EGH54896.1, EGH22392.1, EGH97259.1, NP_(—)793082.1, EGH90852.1, EGH41593.1, NP_(—)252169.1, ZP_(—)01366930.1, YP_(—)001347031.1, ZP_(—)07778021.1, YP_(—)002875182.1, AAA25978.1, ABL84756.1, EGH81248.1, ZP_(—)07795409.1 and particularly preferably AAU44816.1, NP_(—)743567.1, YP_(—)001269622.1, ADR61731.1, AAK71349.1, YP_(—)001670627.1, AAK81868.1, AAQ16175.1, Q9KJH8.1, ACH70299.1, YP_(—)004703658.1, ZP_(—)08139631.1, YP_(—)609790.1, YP_(—)001747923.1, AAK71350.1, and proteins with a polypeptide sequence wherein up to 60%, preferably up to 25%, particularly preferably up to 15%, in particular up to 10, 9, 8, 7, 6, 5, 4, 3, 2 or 1% of the amino acid residues compared to the aforementioned reference sequences are modified by deletion, insertion, substitution or a combination thereof and which still possess at least 50%, preferably 65%, particularly preferably 80%, in particular more than 90% of the activity of the protein with the corresponding, aforementioned reference sequence, wherein 100% activity of the reference protein is understood to mean the increasing of the activity of the cells used as a biocatalyst, i.e. the quantity of substance converted per unit time based on the cell quantity used (units per gram cell dry weight [U/g CDW]) in comparison to the activity of the biocatalyst in the absence of the reference protein, wherein the activity in this connection and in connection with the determination of the activity of the enzyme E_(iib) in general is understood to mean in particular the conversion of dodecanoyl-CoA thioester to dodecanoyl-ACP thioester.

Third Genetic Modification for the Production of Carboxylate Esters

In particular for the production of ω-functionalized carboxylate esters, such as for example ω-hydroxy-, ω-carboxy- or ω-aminocarboxylate esters it is advantageous if the microorganism has a third genetic modification, which compared with the enzymatic activity of the wild type of the microorganism comprises increased activity of at least one of the enzymes E_(iib), E_(v), E_(vi), or E_(vii) which are involved in the conversion of carboxylic acids or ω-functionalized carboxylic acids to carboxylate esters or ω-functionalized carboxylate esters.

In this connection, it is preferable according to the invention that this genetic modification is, compared to the enzymatic activity of the wild type of the microorganism, increased activity of at least one of the enzymes selected from the group

E_(iib) Acyl-CoA (coenzyme A):ACP (acyl carrier protein) transacylase, which converts an ACP thioester into a CoA thioester or a CoA thioester into an ACP thioester, E_(v) Wax ester synthase or alcohol O acyltransferase, preferably of EC 2.3.1.75 or EC 2.3.1.84, which catalyses the synthesis of an ester from an acyl-coenzyme A thioester or an ACP thioester and an alcohol, E_(vi) Acyl-CoA (coenzyme A) synthetase, preferably of EC 6.2.1.3, which catalyses the synthesis of an acyl-coenzyme A thioester, and E_(vii) Acyl thioesterase, preferably of EC 3.1.2.2, EC 3.1.2.4, EC 3.1.2.18, EC 3.1.2.19, EC 3.1.2.20 or EC 3.1.2.22, which catalyses the conversion of an acyl thioester with an alcohol to a carboxylate ester.

In this connection, it is particularly preferable that the third genetic modification comprises combinations of the increased activities of the enzymes selected from

E_(v), E_(vii), E_(v)E_(vi), E_(vi)E_(vii) and E_(vi)E_(vii)E_(iib).

Preferred enzymes E_(iib) in connection with the third genetic modification correspond to the enzymes E_(iib) listed above as preferable in connection with the first genetic modification.

Specific enzymes E_(v)

In cells preferred according to the invention, the enzyme E_(v) is one which comprises sequences selected from:

NP_(—)808414.2, NP_(—)001178653.1, XP_(—)003272721.1, XP_(—)002720111.1, NP_(—)001002254.1, XP_(—)529027.1, XP_(—)002831804.1, BAC28882.1, XP_(—)549056.2, XP_(—)002918053.1, XP_(—)001085075.1, XP_(—)002763005.1, XP_(—)002700092.1, XP_(—)599558.4, EDL95940.1, XP_(—)001496780.1, CAD89267.1, EFB28125.1, YP_(—)004747160.1, YP_(—)004746900.1, YP_(—)004746665.1, YP_(—)004746558.1, YP_(—)004746531.1, YP_(—)004746530.1, YP_(—)004745948.1, YP_(—)004745222.1, YP_(—)004744358.1, YP_(—)004743710.1, YP_(—)002492297.1, AEK40846.1, YP_(—)001847685.1, YP_(—)001712672.1, YP_(—)001706290.1, YP_(—)004724737.1, YP_(—)004723134.1, AEJ51098.1, AEJ48174.1, AEJ47480.1, YP_(—)004392630.1, YP_(—)004099725.1, YP_(—)003912033.1, YP_(—)003652731.1, YP_(—)003301387.1, YP_(—)003298139.1, YP_(—)001509672.1, YP_(—)001505948.1, YP_(—)001432486.1, YP_(—)001432432.1, YP_(—)924893.1, YP_(—)923981.1, YP_(—)922869.1, YP_(—)922597.1, YP_(—)922419.1, ZP_(—)08629145.1, ZP_(—)08628906.1, YP_(—)001380027.1, YP_(—)001280731.1, YP_(—)001280730.1, YP_(—)888966.1, YP_(—)890540.1, YP_(—)888236.1, YP_(—)888223.1, YP_(—)888574.1, YP_(—)884705.1, YP_(—)889488.1, YP_(—)886248.1, YP_(—)882534.1, YP_(—)881069.1, YP_(—)881444.1, YP_(—)883472.1, YP_(—)879642.1, YP_(—)884073.1, YP_(—)880917.1, YP_(—)882201.1, YP_(—)879422.1, YP_(—)707862.1, YP_(—)707847.1, YP_(—)707633.1, YP_(—)707572.1, YP_(—)707571.1, YP_(—)706785.1, YP_(—)706267.1, YP_(—)705586.1, YP_(—)705294.1, YP_(—)702929.1, YP_(—)701572.1, YP_(—)700576.1, YP_(—)700081.1, YP_(—)700033.1, YP_(—)700018.1, YP_(—)700017.1, YP_(—)699999.1, CCB78299.1, CCB78283.1, CCB72233.1, YP_(—)004663601.1, YP_(—)004525283.1, YP_(—)004524901.1, YP_(—)004524237.1, YP_(—)004524223.1, YP_(—)004523752.1, YP_(—)004522677.1, YP_(—)004521797.1, YP_(—)004521441.1, YP_(—)004020500.1, YP_(—)004014348.1, EGO40684.1, EGO38684.1, EGO38655.1, EGO37244.1, EGO36970.1, EGO36701.1, YP_(—)003951335.1, YP_(—)003812176.1, YP_(—)003811992.1, YP_(—)003810691.1, YP_(—)003810418.1, YP_(—)003809501.1, ZP_(—)08574204.1, CCA19760.1, XP_(—)002900672.1, ZP_(—)06414567.1, ZP_(—)06413635.1, ZP_(—)06411773.1, ZP_(—)06411772.1, ZP_(—)06271823.1, ZP_(—)05620754.1, ZP_(—)05360001.1, ZP_(—)04752019.1, ZP_(—)04751943.1, ZP_(—)04750965.1, ZP_(—)04750465.1, ZP_(—)04750453.1, ZP_(—)04750228.1, ZP_(—)04750091.1, ZP_(—)04749363.1, ZP_(—)04749348.1, ZP_(—)04749293.1, ZP_(—)04749287.1, ZP_(—)04749022.1, ZP_(—)04748677.1, ZP_(—)04747379.1, ZP_(—)04747377.1, ZP_(—)04747348.1, ZP_(—)04747282.1, ZP_(—)04747159.1, ZP_(—)04747093.1, ZP_(—)04746958.1, ZP_(—)04717323.1, ZP_(—)04684258.1, ZP_(—)04386203.1, ZP_(—)04385082.1, ZP_(—)04384030.1, ZP_(—)04384029.1, ZP_(—)03534755.1, ZP_(—)01115502.1, ZP_(—)01102322.1, YP_(—)004583872.1, YP_(—)004583323.1, YP_(—)004573656.1, YP_(—)004571392.1, YP_(—)003513699.1, ZP_(—)08553011.1, ZP_(—)08552672.1, YP_(—)003467054.1, YP_(—)003572597.1, YP_(—)579515.1, YP_(—)001136465.1, YP_(—)001136231.1, YP_(—)001135959.1, YP_(—)001135349.1, YP_(—)001133828.1, YP_(—)001133806.1, YP_(—)001133693.1, YP_(—)001133270.1, YP_(—)001132329.1, YP_(—)001131721.1, YP_(—)001131631.1, YP_(—)001073715.1, YP_(—)001073143.1, YP_(—)001072388.1, YP_(—)001072036.1, YP_(—)001071893.1, YP_(—)001071814.1, YP_(—)001071689.1, YP_(—)001070856.1, YP_(—)001069682.1, YP_(—)001069164.1, YP_(—)001068496.1, YP_(—)939377.1, YP_(—)642242.1, YP_(—)641664.1, YP_(—)641419.1, YP_(—)640919.1, YP_(—)640783.1, YP_(—)640704.1, YP_(—)640572.1, YP_(—)640571.1, YP_(—)640494.1, YP_(—)639709.1, YP_(—)639198.1, YP_(—)638523.1, YP_(—)638030.1, YP_(—)637968.1, YP_(—)637380.1, YP_(—)446603.1, NP_(—)001185377.1, NP_(—)200151.2, NP_(—)568547.1, NP_(—)197641.1, NP_(—)200150.1, NP_(—)197139.1, NP_(—)190490.1, NP_(—)190488.1, NP_(—)177356.1, YP_(—)004495408.1, YP_(—)004495023.1, YP_(—)004494197.1, YP_(—)004494168.1, YP_(—)004493973.1, YP_(—)004493936.1, YP_(—)004493628.1, YP_(—)004493589.1, YP_(—)004493509.1, YP_(—)004493477.1, YP_(—)004493462.1, YP_(—)004492352.1, YP_(—)004492155.1, YP_(—)004492039.1, YP_(—)004491716.1, YP_(—)004491715.1, YP_(—)004491501.1, YP_(—)003375642.1, YP_(—)003411203.1, YP_(—)003410436.1, YP_(—)003395271.1, YP_(—)003395089.1, YP_(—)003393635.1, YP_(—)003384208.1, YP_(—)003379551.1, ZP_(—)04388235.1, YP_(—)002134168.1, ZP_(—)01900421.1, ZP_(—)01900085.1, ZP_(—)01899829.1, ZP_(—)01898741.1, BAK05274.1, BAJ93623.1, BAJ97841.1, BAK08349.1, BAJ93204.1, BAJ92722.1, BAK06983.1, BAJ86545.1, BAK02325.1, BAJ85619.1, BAJ84892.1, ZP_(—)05218281.1, ZP_(—)05218149.1, ZP_(—)05217310.1, ZP_(—)05216978.1, ZP_(—)05216447.1, ZP_(—)05216446.1, ZP_(—)05216025.1, ZP_(—)05214687.1, ZP_(—)08476543.1, ZP_(—)04749239.1, YP_(—)823060.1, ADP99639.1, ADP98951.1, ADP98855.1, ADP98710.1, ADP96265.1, ZP_(—)08461736.1, ZP_(—)08461735.1, ZP_(—)07608690.1, YP_(—)045555.1 (encoded by SEQ ID No. 22), YP_(—)872243.1, YP_(—)004009106.1, YP_(—)004008736.1, YP_(—)004008003.1, YP_(—)004007600.1, YP_(—)004006799.1, YP_(—)004006436.1, YP_(—)004006072.1, YP_(—)004005008.1, YP_(—)003486913.1, NP_(—)301898.1, ZP_(—)08434757.1, YP_(—)004079491.1, YP_(—)004078785.1, YP_(—)004077880.1, YP_(—)004076486.1, YP_(—)004076464.1, YP_(—)004076350.1, YP_(—)004075391.1, YP_(—)004074864.1, ZP_(—)01103855.1, YP_(—)465274.1, ZP_(—)08403393.1, ZP_(—)08402717.1, ZP_(—)08402716.1, YP_(—)004427559.1, YP_(—)001277083.1, YP_(—)001276783.1, YP_(—)524767.1, YP_(—)522739.1, YP_(—)521788.1, YP_(—)004335162.1, YP_(—)004333708.1, YP_(—)004332973.1, YP_(—)004332349.1, YP_(—)004157731.1, YP_(—)004224204.1, YP_(—)003275673.1, YP_(—)003275371.1, YP_(—)003274979.1, YP_(—)003274924.1, YP_(—)003274705.1, YP_(—)956544.1, YP_(—)955502.1, YP_(—)955007.1, YP_(—)954887.1, YP_(—)954886.1, YP_(—)954859.1, YP_(—)954399.1, YP_(—)953715.1, YP_(—)953073.1, YP_(—)952592.1, YP_(—)951909.1, YP_(—)951298.1, YP_(—)951083.1, ZP_(—)08287899.1, ZP_(—)08272356.1, ZP_(—)08270967.1, CCA60099.1, CCA56737.1, YP_(—)983728.1, YP_(—)550833.1, YP_(—)549124.1, YP_(—)121795.1, YP_(—)120815.1, YP_(—)118589.1, YP_(—)117783.1, YP_(—)117375.1, YP_(—)003646883.1, YP_(—)003646055.1, YP_(—)003645661.1, EGE49469.1, ZP_(—)08234310.1, CBZ53121.1, YP_(—)004010866.1, EGE24961.1, EGE18726.1, EGE15701.1, EGE12950.1, EGE10026.1, EGB03968.1, ZP_(—)08206563.1, ZP_(—)08205089.1, ZP_(—)08204958.1, ZP_(—)08204416.1, ZP_(—)08203326.1, YP_(—)714381.1, YP_(—)713817.1, YP_(—)694462.1, YP_(—)693524.1, YP_(—)003341775.1, YP_(—)003339587.1, ZP_(—)08197177.1, ADW01905.1, YP_(—)004242683.1, ZP_(—)07484742.2, ZP_(—)07441979.2, ZP_(—)07441978.2, ZP_(—)07437333.2, ZP_(—)06960424.1, ZP_(—)06801236.1, ZP_(—)06799517.1, ZP_(—)05769718.1, ZP_(—)05768326.1, ZP_(—)05767970.1, ZP_(—)05766272.1, ZP_(—)05763839.1, YP_(—)003204265.1, YP_(—)003203570.1, YP_(—)003200768.1, YP_(—)003134884.1, YP_(—)003134608.1, ZP_(—)05140320.1, NP_(—)001140997.1, EEE64643.1, EEE55448.1, EEE32548.1, ZP_(—)03534756.1, ZP_(—)03533653.1, ZP_(—)03531929.1, EEC71274.1, EAY98969.1, EAY75974.1, EAY75973.1, ADZ24988.1, ZP_(—)08157247.1, ZP_(—)08156660.1, ZP_(—)08156249.1, ZP_(—)08153292.1, ZP_(—)08152876.1, ZP_(—)08152662.1, YP_(—)002946672.1, YP_(—)960669.1, YP_(—)960629.1, YP_(—)960328.1, YP_(—)958134.1, YP_(—)957462.1, YP_(—)001022272.1, ZP_(—)08123690.1, ZP_(—)08120547.1, ZP_(—)08119498.1, EGB29195.1, EGB27143.1, YP_(—)003770089.1, YP_(—)003769971.1, YP_(—)003764703.1, YP_(—)003764513.1, YP_(—)003103950.1, YP_(—)003168536.1, YP_(—)003168331.1, YP_(—)003166844.1, CAJ88696.1, NP_(—)769520.1, YP_(—)001141853.1, YP_(—)001108534.1, YP_(—)001106516.1, YP_(—)907824.1, YP_(—)907344.1, YP_(—)906945.1, YP_(—)906856.1, YP_(—)906855.1, YP_(—)906831.1, YP_(—)906494.1, YP_(—)906243.1, YP_(—)905962.1, YP_(—)905765.1, YP_(—)905343.1, YP_(—)905239.1, YP_(—)325796.1, YP_(—)130413.1, NP_(—)625255.1, NP_(—)624462.1, NP_(—)338129.1, NP_(—)338004.1, NP_(—)337859.1, NP_(—)337740.1, NP_(—)337694.1, NP_(—)336266.1, NP_(—)335919.1, NP_(—)335351.1, NP_(—)334638.1, NP_(—)218257.1, NP_(—)218251.1, NP_(—)217997.1, NP_(—)217888.1, NP_(—)217751.1, NP_(—)217750.1, NP_(—)217646.1, NP_(—)217604.1, NP_(—)217603.1, NP_(—)217000.1, NP_(—)216801.1, NP_(—)216276.1, NP_(—)215941.1, NP_(—)215410.1, NP_(—)214735.1, ZP_(—)04661667.1, EFW44815.1, EFW44455.1, ZP_(—)08024634.1, ZP_(—)08024620.1, ZP_(—)08023777.1, ZP_(—)08023597.1, YP_(—)002784032.1, YP_(—)002783585.1, YP_(—)002782904.1, YP_(—)002782647.1, YP_(—)002780099.1, YP_(—)002779887.1, YP_(—)002778497.1, YP_(—)002777657.1, YP_(—)002777402.1, ZP_(—)07966321.1, ZP_(—)07944768.1, CBI21867.3, CBI40547.3, CBI40544.3, CBI40540.3, CBI40536.3, CBI40534.3, CBI40533.3, CBI32385.3, ZP_(—)05765756.1, ZP_(—)05765643.1, ZP_(—)05765597.1, ZP_(—)05765596.1, YP_(—)001705267.1, YP_(—)001704692.1, YP_(—)001704281.1, YP_(—)001702654.1, YP_(—)001701260.1, ZP_(—)05770434.1, ZP_(—)05766274.1, ZP_(—)05762133.1, ZP_(—)05762130.1, ZP_(—)01101223.1, YP_(—)481580.1, YP_(—)979623.1, YP_(—)979196.1, ZP_(—)07414300.2, ZP_(—)03537340.1, ZP_(—)03537339.1, ZP_(—)03536772.1, ZP_(—)03536404.1, ZP_(—)03433478.1, ZP_(—)03430367.1, ZP_(—)03430260.1, ZP_(—)03429345.1, ZP_(—)03428583.1, ZP_(—)03426905.1, ZP_(—)03426458.1, ZP_(—)03426456.1, ZP_(—)03426455.1, ZP_(—)03425014.1, ZP_(—)03424082.1, ZP_(—)03421649.1, ZP_(—)03419291.1, ZP_(—)03418394.1, ZP_(—)03417976.1, ZP_(—)03414875.1, ZP_(—)06952098.1, ZP_(—)05528769.1, ZP_(—)05527907.1, ZP_(—)05227984.1, ZP_(—)05227897.1, ZP_(—)05227653.1, ZP_(—)05227585.1, ZP_(—)05227420.1, ZP_(—)05227202.1, ZP_(—)05226387.1, ZP_(—)05226386.1, ZP_(—)05225355.1, ZP_(—)05225200.1, ZP_(—)05223431.1, ZP_(—)05223402.1, ZP_(—)04697793.1, ZP_(—)02550609.1, ZP_(—)02548969.1, EEE25493.1, ABO13188.2, ZP_(—)07205208.1, YP_(—)589436.1, BAJ33896.1, ZP_(—)07718107.1, ZP_(—)07717513.1, ZP_(—)07717390.1, ZP_(—)07716424.1, ZP_(—)04384387.1, ZP_(—)07376578.1, ZP_(—)06871097.1, ZP_(—)06852444.1, ZP_(—)06852442.1, ZP_(—)06852283.1, ZP_(—)06852150.1, ZP_(—)06852032.1, ZP_(—)06850980.1, ZP_(—)06850766.1, ZP_(—)06850644.1, ZP_(—)06849846.1, ZP_(—)06849446.1, ZP_(—)06849265.1, ZP_(—)06848894.1, ZP_(—)06848550.1, ZP_(—)06847321.1, ZP_(—)06847245.1, ZP_(—)06728640.1, ZP_(—)06155537.1, ZP_(—)03822106.1, ZP_(—)03822105.1, ZP_(—)03264909.1, ZP_(—)01915979.1, ZP_(—)01914209.1, ZP_(—)01909198.1, ZP_(—)01895985.1, ZP_(—)01893763.1, ZP_(—)01893601.1, ZP_(—)01893547.1, ZP_(—)01864269.1, ZP_(—)01736818.1, ZP_(—)01693481.1, ZP_(—)01626518.1, ZP_(—)01616172.1, ZP_(—)01461648.1, ZP_(—)01439861.1, ZP_(—)01311414.1, ZP_(—)01222733.1, ZP_(—)01038993.1, ZP_(—)00997001.1, ZP_(—)06533596.1, ZP_(—)07308012.1, ZP_(—)07282351.1, ZP_(—)07282257.1, ZP_(—)07278697.1, ZP_(—)07277986.1, ZP_(—)07277799.1, ZP_(—)07011797.1, ZP_(—)06913634.1, ZP_(—)06711075.1, ZP_(—)06575037.1, ZP_(—)06523715.1, ZP_(—)06522644.1, ZP_(—)06520408.1, ZP_(—)06518751.1, ZP_(—)06514733.1, ZP_(—)06511304.1, ZP_(—)06510466.1, ZP_(—)06509700.1, ZP_(—)06504004.1, ZP_(—)06452618.1, ZP_(—)06451687.1, ZP_(—)06450049.1, ZP_(—)06444722.1, ZP_(—)06443996.1, ZP_(—)06443677.1, ZP_(—)06438510.1, ZP_(—)06435077.1, ZP_(—)06434554.1, ZP_(—)06432969.1, ZP_(—)06431341.1, ZP_(—)06430915.1, ZP_(—)05129423.1, ZP_(—)05127637.1, ZP_(—)05126217.1, ZP_(—)05096686.1, ZP_(—)05095013.1, ZP_(—)05094400.1, ZP_(—)05093434.1, ZP_(—)05043539.1, ZP_(—)05041631.1, ZP_(—)04959394.1, ZP_(—)04956551.1, ZP_(—)01052702.1, YP_(—)437020.1, YP_(—)436128.1, YP_(—)432512.1, YP_(—)432391.1, ZP_(—)06072118.1, ZP_(—)06069021.1, ZP_(—)06065092.1, ZP_(—)06062254.1, YP_(—)003032200.1, YP_(—)003030813.1, YP_(—)002766854.1, YP_(—)002766842.1, YP_(—)002766292.1, YP_(—)002765623.1, YP_(—)002765076.1, YP_(—)002764977.1, YP_(—)002764976.1, YP_(—)002764693.1, YP_(—)002764633.1, YP_(—)002646305.1, YP_(—)002646304.1, YP_(—)001853537.1, YP_(—)001853530.1, YP_(—)001853214.1, YP_(—)001852100.1, YP_(—)001851711.1, YP_(—)001851686.1, YP_(—)001851684.1, YP_(—)001851611.1, YP_(—)001851610.1, YP_(—)001851579.1, YP_(—)001850950.1, YP_(—)001850935.1, YP_(—)001850900.1, YP_(—)001850899.1, YP_(—)001850378.1, YP_(—)001849911.1, YP_(—)001849825.1, YP_(—)001849624.1, YP_(—)001849470.1, YP_(—)001848848.1, YP_(—)001848784.1, YP_(—)001822237.1, YP_(—)001289190.1, YP_(—)001289078.1, YP_(—)001288434.1, YP_(—)001287727.1, YP_(—)001286168.1, YP_(—)001085790.1, YP_(—)856793.1, YP_(—)629387.1, YP_(—)615587.1, YP_(—)615252.1, YP_(—)457389.1, YP_(—)263530.1, NP_(—)962591.1, NP_(—)962411.1, NP_(—)962281.1, NP_(—)961234.1, NP_(—)960903.1, NP_(—)960387.1, NP_(—)960090.1, NP_(—)959281.1, NP_(—)959065.1, NP_(—)857403.1, NP_(—)857149.1, NP_(—)857148.1, NP_(—)857047.1, NP_(—)856907.1, NP_(—)856759.1, NP_(—)856156.1, NP_(—)855443.1, NP_(—)855112.1, NP_(—)853892.1, NP_(—)828432.1, NP_(—)603766.1, XP_(—)003081224.1, YP_(—)003778608.1, YP_(—)003730939.1, XP_(—)003059244.1, ADI13131.1, XP_(—)002992800.1, XP_(—)002963877.1, XP_(—)001419779.1, XP_(—)002988280.1, XP_(—)002987493.1, CBH32551.1, CBH32550.1, CBH19575.1, CBH19574.1, YP_(—)003627553.1, XP_(—)002879777.1, XP_(—)002877657.1, XP_(—)002877655.1, XP_(—)002873570.1, XP_(—)002871716.1, XP_(—)002870738.1, XP_(—)002868506.1, XP_(—)002865972.1, XP_(—)002864239.1, XP_(—)002862308.1, ZP_(—)05823139.1, NP_(—)001043877.1, ZP_(—)06693274.1, ZP_(—)06058985.1, NP_(—)001044374.1, XP_(—)002835451.1, XP_(—)002787542.1, XP_(—)002785958.1, XP_(—)002785645.1, XP_(—)002783220.1, XP_(—)002774061.1, XP_(—)002767852.1, XP_(—)002766051.1, XP_(—)002765456.1, XP_(—)002765455.1, XP_(—)002677788.1, XP_(—)002671612.1, XP_(—)002736281.1, CBA31373.1, XP_(—)002184474.1, XP_(—)002325936.1, XP_(—)002323705.1, XP_(—)002325937.1, XP_(—)002323911.1, XP_(—)002323706.1, XP_(—)002328965.1, XP_(—)002318416.1, XP_(—)002310400.1, ACY38597.1, ACY38596.1, ACY38595.1, ACY38594.1, ACY38593.1, ACY38592.1, ACY38591.1, ACY38590.1, ACX81315.1, ACX81314.1, XP_(—)001868729.1, XP_(—)001847517.1, XP_(—)001847515.1, XP_(—)002502575.1, ACU20370.1, ACU18073.1, XP_(—)002523348.1, XP_(—)002516707.1, XP_(—)002429016.1, BAH89673.1, XP_(—)002440221.1, XP_(—)002459294.1, XP_(—)002458560.1, XP_(—)320167.4, XP_(—)001780431.1, XP_(—)002364905.1, XP_(—)002263196.1, XP_(—)002263137.1, XP_(—)002263409.1, XP_(—)002263252.1, XP_(—)002268615.1, XP_(—)002278404.1, XP_(—)002274522.1, XP_(—)002282418.1, XP_(—)001633379.1, XP_(—)001632267.1, XP_(—)001632004.1, XP_(—)001622638.1, XP_(—)002155609.1, XP_(—)759225.1, XP_(—)002152406.1, XP_(—)001914129.1, XP_(—)001738032.1, XP_(—)001731626.1, XP_(—)001209859.1, CAN79451.1, CAN78449.1, CAN72806.1, CAN71951.1, CAN71950.1, CAN76656.1, CAN62907.1, AAZ08051.1, ABO21022.1, ABO21021.1, ABO21020.1, ABJ96321.1, BAF01088.1, XP_(—)758106.1, BAC42871.1, BAB09801.1, BAB09102.1, in particular YP_(—)045555.1 (encoded by SEQ ID No. 22) and NP_(—)808414.2 and proteins with a polypeptide sequence wherein up to 60%, preferably up to 25%, particularly preferably up to 15%, in particular up to 10, 9, 8, 7, 6, 5, 4, 3, 2 or 1% of the amino acid residues compared to the aforementioned reference sequences are modified by deletion, insertion, substitution or a combination thereof and which still possess at least 50%, preferably 65%, particularly preferably 80%, in particular more than 90% of the activity of the protein with the corresponding, aforementioned reference sequence, wherein 100% activity of the reference protein is understood to mean the increasing of the activity of the cells used as a biocatalyst, i.e. the quantity of substance converted per unit time based on the cell quantity used (units per gram cell dry weight [U/g CDW]) in comparison to the activity of the biocatalyst in the absence of the reference protein, wherein the activity in this connection and in connection with the determination of the activity of the enzyme E_(v) in general is understood to mean in particular the conversion of dodecanoyl-CoA thioester and/or dodecanoyl-ACP thioester with methanol to dodecanoyl methyl esters.

If the enzyme E_(v) is an alcohol O-acyltransferase of EC 2.3.1.84, then it is preferable that this is selected from:

EGA72844.1, NP_(—)015022.1, S69991, AAP72991.1, EDN63695.1, BAA05552.1, AAP72992.1, S69992, AAP72995.1, XP_(—)002552712.1, XP_(—)001646876.1, XP_(—)002551954.1, EGA82692.1, EDN61766.1, EGA86689.1, EGA74966.1, AAU09735.1, NP_(—)011693.1, XP_(—)445666.1, BAA13067.1, AAP72993.1, EGA62172.1, XP_(—)455762.1, EGA58658.1, and proteins with a polypeptide sequence wherein up to 60%, preferably up to 25%, particularly preferably up to 15%, in particular up to 10, 9, 8, 7, 6, 5, 4, 3, 2 or 1% of the amino acid residues compared to the aforementioned reference sequences are modified by deletion, insertion, substitution or a combination thereof and which still possess at least 50%, preferably 65%, particularly preferably 80%, in particular more than 90% of the activity of the protein with the corresponding, aforementioned reference sequence, wherein 100% activity of the reference protein is understood to mean the increasing of the activity of the cells used as a biocatalyst, i.e. the quantity of substance converted per unit time based on the cell quantity used (units per gram cell dry weight [U/g CDW]) in comparison to the activity of the biocatalyst in the absence of the reference protein, wherein the activity in this connection and in connection with the determination of the activity of the enzyme E_(v) in general is understood to mean in particular the conversion of dodecanoyl-CoA thioester with methanol to dodecanoyl methyl ester.

Microorganisms preferred according to the invention are those which are obtained when the microorganisms listed below having a third genetic modification in the sense of the invention are used as the starting point, in that they are provided with a first and second genetic modification and optionally at least one further genetic modification in the sense of the invention.

WO2007136762 A2 describes, particularly on pages 2 to 4 and 21 to 24, FIGS. 2 to 4, practical examples 1, 2 and 5 to 7 and claims 1, 2, 5, 6, 9 to 27 and 33, microorganisms preferably used according to the invention which have a third genetic modification, so that compared to their wild type they are capable of forming more fatty acids and fatty acid derivatives, in particular fatty acid esters, wax esters, hydrocarbons and fatty alcohols, from at least one simple carbon source. The document also describes enzymes E_(i) preferred according to the invention and the sequences thereof, particularly on pages 21 to 24, in table 10 and FIG. 10.

Specific enzymes E_(vi)

In cells preferred according to the invention, the enzyme E_(vi) is one which comprises sequences selected from YP_(—)001724804.1 (encoded by SEQ ID No. 21)

and proteins with a polypeptide sequence wherein up to 60%, preferably up to 25%, particularly preferably up to 15%, in particular up to 10, 9, 8, 7, 6, 5, 4, 3, 2 or 1% of the amino acid residues compared to the aforementioned reference sequence are modified by deletion, insertion, substitution or a combination thereof and which still possess at least 50%, preferably 65%, particularly preferably 80%, in particular more than 90% of the activity of the protein with the corresponding, aforementioned reference sequence, wherein 100% activity of the reference protein is understood to mean the increasing of the activity of the cells used as a biocatalyst, i.e. the quantity of substance converted per unit time based on the cell quantity used (units per gram cell dry weight [U/g CDW]) in comparison to the activity of the biocatalyst in the absence of the reference protein, wherein the activity in this connection and in connection with the determination of the activity of the enzyme E_(vi) in general is understood to mean in particular the synthesis of dodecanoyl-CoA thioester.

Specific Enzymes E_(vii)

Microorganisms preferred according to the invention are those which are obtained when the microorganisms listed below having a third genetic modification in the sense of the invention are used as the starting point, in that they are provided with a first and second genetic modification and optionally at least one further genetic modification in the sense of the invention.

WO2010075483 A2 describes, particularly in paragraphs [0061] to [0090] and [0287] to [0367], FIGS. 1, 4 and 5, practical examples 1 to 38 and claims 18 to 26, microorganisms preferably used according to the invention which have a third genetic modification, so that compared to their wild type they are capable of forming more fatty acids and fatty acid derivatives, in particular fatty acids, fatty acid methyl esters, fatty acid ethyl esters, fatty alcohols, fatty alkyl acetates, fatty aldehydes, fatty amines, fatty amides, fatty sulphates, fatty ethers, ketones, alkanes, internal and terminal olefins, dicarboxylic acids, α,ω-dicarboxylic acids and α,ω-diols, from at least one simple carbon source. The document also describes enzymes E_(i) preferred according to the invention and the sequences thereof, particularly in paragraphs [0012] to [0060], tables 7, 17, 26 and 27, FIGS. 1, 44 to 47 and 55 to 59, practical examples 1 to 38 and claims 1 to 17.

Fourth Genetic Modification for the Production of ω-Hydroxy- or ω-Oxo-Functionalized Carboxylic Acids and Esters

For the case where the production of ω-hydroxy- or ω-oxo-functionalized carboxylic acids and esters—also as precursor stages for further ω-functionalizations such as for example ω-amination—is desired, it can be advantageous suitably to reduce the corresponding carboxylic acids or esters which have been oxidized in the ω position up to the carboxy function in the microorganism.

For this, microorganisms preferred according to the invention have a fourth genetic modification which, compared with the enzymatic activity of the wild type of the microorganism, comprises increased activity of at least one of the enzymes selected from the group

E_(iib) Acyl-CoA (coenzyme A):ACP (acyl carrier protein) transacylase, which converts an ACP thioester into a CoA thioester or a CoA thioester into an ACP thioester, E_(vi) Acyl-CoA (coenzyme A) synthetase, preferably of EC 6.2.1.3, which preferentially catalyses the synthesis of an acyl-coenzyme A thioester, E_(vii) Acyl-CoA (coenzyme A) reductase, preferably of EC 1.2.1.42 or EC 1.2.1.50, which preferentially catalyses the reduction of an acyl-coenzyme A thioester to the corresponding alkan-1-al or alkan-1-ol E_(ix) Fatty acid reductase (also fatty aldehyde dehydrogenase or arylaldehyde oxidoreductase), preferably of EC 1.2.1.3, EC 1.2.1.20 or EC 1.2.1.48, which preferentially catalyses the reduction of an alkanoic acid to the corresponding alkan-1-al, and E_(x) Acyl-ACP (acyl carrier protein) reductase, preferably of EC 1.2.1.80, which preferentially catalyses the reduction of an acyl-ACP thioester to the corresponding alkan-1-al or alkan-1-ol.

In this connection, it is particularly preferable that the fourth genetic modification comprises combinations of increased activities of the enzymes selected from E_(viii), E_(ix), E_(x), E_(vi)E_(viii) and E_(vi)E_(x)E_(iib).

Preferred enzymes E_(iib) in connection with the fourth genetic modification correspond to the enzymes E_(iib) listed above as preferable in connection with the first and third genetic modification.

Thus configured organisms preferred according to the invention are also outstandingly suitable for the production of compounds which are selected from α,ω-alkanediols, α,ω-alkanedialdehydes, α-oxo-ω-hydroxyalkanes and α,ω-alkanediamines, α,ω-alkenediols, α,ω-alkenedialdehydes, α-oxo-ω-hydroxyalkenes and α,ω-alkenediamines, since compounds of these classes are produced in significant quantities as well as the ω-functionalized carboxylic acids and ω-functionalized carboxylate esters.

In this connection, it may be mentioned that the alkene derivatives in particular arise through the conversion of unsaturated fatty acids formed by the microorganism, such as for example palmitoleic acid, oleic acid, linolic acid, adinolenic acid and γ-linolenic acid.

Specific Enzymes E_(viii)

Microorganisms preferred according to the invention are those which are obtained when the microorganisms listed below having a fourth genetic modification in the sense of the invention are used as the starting point, in that they are provided with a first and second genetic modification and optionally at least one further genetic modification in the sense of the invention.

WO2011008565 A1 describes, particularly in paragraphs [0021], [0103] to [0106], [0108] and [0129], microorganisms preferably used according to the invention which have a fourth genetic modification, so that compared to their wild type they are capable of forming more fatty acids and fatty acid derivatives, in particular fatty acids, fatty aldehydes, fatty alcohols, alkanes and fatty acid esters from at least one simple carbon source. The document also describes enzymes E_(viii) preferred according to the invention and the sequences thereof, particularly in paragraphs [0104] to [0106] and [0108] and [0129] and practical example 11.

WO2008151149 A2 describes, particularly in paragraphs [0009], [0015] to [0037], [0053], [0071], [0171], [0174] to [0191], [0274] and [0396], claims 53 to 114, 188 to 206 and 344 to 355 and tables 1 to 3, microorganisms preferably used according to the invention which have a fourth genetic modification, so that compared to their wild type they are capable of forming more microbial oil from at least one simple carbon source. The document also describes enzymes E_(viii) preferred according to the invention and the sequences thereof, particularly in paragraphs [0255] to [0261] and [0269] and tables 6 and 7.

WO2007136762 A2 describes, particularly on pages 2 to 4 and 19 to 20, FIGS. 2 to 4, practical examples 2 to 7 and claims 4, 8 to 27 and 33, microorganisms preferably used according to the invention which have a fourth genetic modification, so that compared to their wild type they are capable of forming more fatty acids and fatty acid derivatives, in particular fatty acid esters, wax esters, hydrocarbons and fatty alcohols, from at least one simple carbon source. The document also describes enzymes E_(viii) preferred according to the invention and the sequences thereof, particularly on pages 19 to 20, in table 10 and FIG. 10.

WO2011019858 A1 describes, particularly in paragraphs [0015] to [0020], [0064] to [0074], [0085] to [0086] and [0092] to [0099], practical examples 1 to 13, FIG. 1 and claims 1 to 14, microorganisms preferably used according to the invention which have a fourth genetic modification, so that compared to their wild type they are capable of forming more fatty acids and fatty acid derivatives, in particular fatty alcohols, from at least one simple carbon source. The document also describes enzymes E_(viii) preferred according to the invention and the sequences thereof, particularly in paragraphs [0004] to [0007] and [0075] to [0080] and practical examples 1 to 13.

WO2009140695 A1 describes, particularly in paragraphs [0031] to [0040], [0051] and [0214] to [0233], practical examples 22 to 24, table 1, FIG. 40, practical examples 5 to 24 and 28 to 30 and claims 29 to 30, microorganisms preferably used according to the invention which have a fourth genetic modification, so that compared to their wild type they are capable of forming more fatty acids and fatty acid derivatives, in particular hydrocarbons, from at least one simple carbon source. The document also describes enzymes E_(viii) preferred according to the invention and the sequences thereof, particularly in paragraphs [0023] to [0030], [0056], [0066] to [0069] and [0193] to [0208], table 1, FIG. 39, practical examples 5 to 24 and 28 to 30 and claims 69 to 74.

WO2011008535 A1 describes, particularly in paragraphs [0023] to [0024], and [0133] to [0158], FIG. 13, claims 39 and 45 to 47 and practical examples 1 to 5, microorganisms preferably used according to the invention which have a fourth genetic modification, so that compared to their wild type they are capable of forming more fatty acids and fatty acid derivatives, in particular carboxylic acids, hydroxycarboxylic acids and lactones thereof from at least one simple carbon source. The document also describes enzymes E_(viii) preferred according to the invention and the sequences thereof, particularly in paragraphs [0017] to [0022], [0084] to [0132], FIGS. 2 to 12, claims 31 to 37 and 40 to 44 and practical examples 1 to 5.

WO2010063031 A2 describes, particularly in paragraphs [0007], [0092] to [0100], [0181] to [0183] and [0199] to [0213], microorganisms preferably used according to the invention which have a fourth genetic modification, so that compared to their wild type they are capable of forming more microbial oil from at least one simple carbon source. The document also describes enzymes E_(viii) preferred according to the invention and the sequences thereof, particularly in paragraphs [0191] to [0194] and tables 4 and 5.

WO2010063032 A2 describes, particularly in paragraphs [0007], [0092] to [0100], [0181] to [0183] and [0199] to [0213], microorganisms preferably used according to the invention which have a fourth genetic modification, so that compared to their wild type they are capable of forming more microbial oil from at least one simple carbon source. The document also describes enzymes E_(viii) preferred according to the invention and the sequences thereof, particularly in paragraphs [0191] to [0194] and tables 4 and 5.

Specific Enzymes E_(ix)

Microorganisms preferred according to the invention are those which are obtained when the microorganisms listed below having a fourth genetic modification in the sense of the invention are used as the starting point, in that they are provided with a first and second genetic modification and optionally at least one further genetic modification in the sense of the invention.

WO2011019858 A1 describes, particularly in paragraphs [0004] to [0008], [0064] to [0074], [0085] to [0086], [0095] to [0099], practical examples 1 to 13, FIG. 1 and claim 7, microorganisms preferably used according to the invention which have a fourth genetic modification, so that compared to their wild type they are capable of forming more fatty acids and fatty acid derivatives, in particular fatty alcohols, from at least one simple carbon source. The document also describes enzymes E_(ix) preferred according to the invention and the sequences thereof, particularly in paragraphs [0008] to [0009], [0074] and [0081] to [0082] and practical examples 1 to 13.

WO2010135624 A2 describes, particularly in paragraphs [0005], [0067] to [0085] and [0092] to [0102], claims 13 to 17 and practical examples 1 to 4, microorganisms preferably used according to the invention which have a fourth genetic modification, so that compared to their wild type they are capable of forming more fatty acids and fatty acid derivatives, in particular carboxylic acids, hydroxycarboxylic acids and lactones thereof, from at least one simple carbon source. The document also describes enzymes E₁ preferred according to the invention and the sequences thereof, particularly in paragraphs [0005] to [0006] and [0086] to [0090], FIGS. 3 to 7, claim 28 and practical examples 1 to 4.

WO2010062480 A2 describes, particularly in paragraphs [0022] to [0174] and [0292] to [0316], practical examples 1 and 3 to 8, FIG. 9 and claims 17 and 24, microorganisms preferably used according to the invention which have a fourth genetic modification, so that compared to their wild type they are capable of forming more fatty acids and fatty acid derivatives, in particular fatty alcohols, from at least one simple carbon source. The document also describes enzymes E_(ix) preferred according to the invention and the sequences thereof, particularly in paragraphs [0019] to [0032] and [0263] to [0286], table 1, FIGS. 6 to 8 and practical examples 1 and 3 to 8.

WO201042664 A2 describes, particularly in paragraphs [0236] to [0261], practical example 2, FIGS. 1 and 5 and claim 25, microorganisms preferably used according to the invention which have a fourth genetic modification, so that compared to their wild type they are capable of forming more fatty acids and fatty acid derivatives, in particular fatty alcohols, from at least one simple carbon source. The document also describes enzymes E_(ix) preferred according to the invention and the sequences thereof, particularly in paragraphs [0211] to [0233], FIGS. 2 to 4 and practical examples 1 to 2.

Specific Enzymes E_(x)

Microorganisms preferred according to the invention are those which are obtained when the microorganisms listed below having a fourth genetic modification in the sense of the invention are used as the starting point, in that they are provided with a first and second genetic modification and optionally at least one further genetic modification in the sense of the invention.

WO2007136762 A2 describes, particularly on pages 2 to 4 and 19 to 20, FIGS. 2 to 4, practical examples 2 to 7 and claims 4, 8 to 27 and 33, microorganisms preferably used according to the invention which have a fourth genetic modification, so that compared to their wild type they are capable of forming more fatty acids and fatty acid derivatives, in particular fatty acid esters, wax esters, hydrocarbons and fatty alcohols, from at least one simple carbon source. The document also describes enzymes E_(x) preferred according to the invention and the sequences thereof, particularly on pages 19 to 20, in table 10 and FIG. 10.

WO2011019858 A1 describes, particularly in paragraphs [0015] to [0020], [0064] to [0074], [0085] to [0086] and [0092] to [0099], practical examples 1 to 13, FIG. 1 and claims 1 to 14, microorganisms preferably used according to the invention which have a fourth genetic modification, so that compared to their wild type they are capable of forming more fatty acids and fatty acid derivatives, in particular fatty alcohols, from at least one simple carbon source. The document also describes enzymes E_(x) preferred according to the invention and the sequences thereof, particularly in paragraphs [0004] to [0007] and [0075] to [0080] and practical examples 1 to 13.

WO2009140695 A1 describes, particularly in paragraphs [0031] to [0040], [0051] and [0214] to [0233], practical examples 22 to 24, table 1, FIG. 40, practical examples 5 to 24 and 28 to 30 and claim 29, microorganisms preferably used according to the invention which have a fourth genetic modification, so that compared to their wild type they are capable of forming more fatty acids and fatty acid derivatives, in particular hydrocarbons, from at least one simple carbon source. The document also describes enzymes E_(x) preferred according to the invention and the sequences thereof, particularly in paragraphs [0023] to [0030], [0056], [0066] to [0069] and [0193] to [0208], table 1, FIG. 39, practical examples 5 to 24 and 28 to 30 and claims 69 to 74.

WO2011008535 A1 describes, particularly in paragraphs [0023] to [0024], and [0133] to [0158], FIG. 13, claims 39 and 45 to 47 and practical examples 1 to 5, microorganisms preferably used according to the invention which have a fourth genetic modification, so that compared to their wild type they are capable of forming more fatty acids and fatty acid derivatives, in particular carboxylic acids, hydroxycarboxylic acids and lactones thereof, from at least one simple carbon source. The document also describes enzymes E_(x) preferred according to the invention and the sequences thereof, particularly in paragraphs [0017] to [0022], [0084] to [0132], FIGS. 2 to 12, claims 31 to 37 and 40 to 44 and practical examples 1 to 5.

Fifth Genetic Modification for Suppression of the Degradation of Carboxylic Acids- and Carboxylic Acid Derivatives

Also preferable according to the invention are microorganisms which have a fifth genetic modification which comprises, compared with the enzymatic activity of the wild type of the microorganism, decreased activity of at least one of the enzymes selected from the group

E_(a) Acyl-CoA synthetase, preferably of EC 6.2.1.3, which catalyses the synthesis of an acyl-coenzyme A thioester, E_(b) Acyl-CoA dehydrogenase, preferably of EC 1.3.99.-, EC 1.3.99.3, or EC 1.3.99.13, which catalyses the oxidation of an acyl-coenzyme A thioester to the corresponding enoyl-coenzyme A thioester, E_(c) Acyl-CoA-oxidase, preferably of EC 1.3.3.6, which catalyses the oxidation of an acyl-coenzyme A thioester to the corresponding enoyl-coenzyme A thioester, E_(d) Enoyl-CoA hydratase, preferably of EC 4.2.1.17 or EC 4.2.1.74, which catalyses the hydration of an enoyl-coenzyme A thioester to the corresponding 3-hydroxyacyl-coenzyme A thioester, E_(e) 3-hydroxyacyl-CoA dehydrogenase, preferably of EC 1.1.1.35 or EC 1.1.1.211, which catalyses the oxidation of a 3-hydroxyacyl-coenzyme A thioester to the corresponding 3-oxoacyl-coenzyme A thioester and E_(f) Acetyl-CoA acyltransferase, preferably of EC 2.3.1.16, which catalyses the transfer of an acyl residue from a 3-oxoacyl-coenzyme A thioester to coenzyme A and thus creates an acyl-coenzyme A thioester shortened by two carbon atoms.

This has the technical effect that depletion of the carboxylic acids and carboxylate esters formed in increased quantity through the first genetic modification, but also of the ω-functionalized carboxylic acids and carboxylate esters formed in increased quantity through the second, third and fourth genetic modification, is prevented.

Specific Enzymes E_(a)

It is also preferable according to the invention that the enzyme E_(a) in the cells according to the invention is one which comprises the sequence NP 416319.1.

and proteins with a polypeptide sequence wherein up to 60%, preferably up to 25%, particularly preferably up to 15%, in particular up to 10, 9, 8, 7, 6, 5, 4, 3, 2 or 1% of the amino acid residues are modified by deletion, insertion, substitution or a combination thereof and which still possess at least 50%, preferably 65%, particularly preferably 80%, in particular more than 90% of the activity of the protein with the corresponding, aforementioned reference sequence, wherein 100% activity of the reference protein is understood to mean the increasing of the activity of the cells used as a biocatalyst, i.e. the quantity of substance converted per unit time based on the cell quantity used (units per gram cell dry weight [U/g CDW]) in comparison to the activity of the biocatalyst in the absence of the reference protein, wherein the activity in this connection and in connection with the determination of the activity of the enzyme E_(a) in general is understood to mean in particular the synthesis of dodecanoyl-CoA thioester.

Specific Enzymes E_(b)

It is also preferable according to the invention that in the cells according to the invention the enzyme E_(b) is one which comprises sequences selected from:

AP_(—)000876.1, ZP_(—)08341828.1, YP_(—)002291517.1, ZP_(—)08393771.1, EFW53921.1, YP_(—)003227327.1, YP_(—)001461409.1, AEG35025.1, YP_(—)002385739.1, EGJ00024.1, ZP_(—)08352177.1, ZP_(—)03070250.1, ZP_(—)08367389.1, EGM63466.1, CBI99746.1, ZP_(—)06660773.1, ZP_(—)08372569.1, YP_(—)309282.2, YP_(—)001879017.1, YP_(—)003497883.1, ACI71032.1, YP_(—)002406464.1, EGB79412.1, EFZ76765.1, ZP_(—)07145000.1, ZP_(—)07151031.1, AAZ87047.1, EFZ56676.1, ZP_(—)06656148.1, EGB35012.1, EGB71054.1, EFW49392.1, ZP_(—)07183316.1, YP_(—)002396328.1, YP_(—)002327805.1, ZP_(—)03027602.1, AAG54546.1, YP_(—)001742341.1, ZP_(—)04538240.1, EFX12717.1, ACI71029.1, NP_(—)285938.2, ZP_(—)03064986.1, ZP_(—)07120505.1, YP_(—)539295.2, ZP_(—)03049609.1, ZP_(—)06652178.1, AAP15817.1, NP_(—)706224.3, ABI99723.1, EGB60663.1, EFW71911.1, EGH38574.1, YP_(—)668186.1, EGK29152.1, EGC05203.1, ZP_(—)02801146.2, YP_(—)687886.1, ZP_(—)08346491.1, EGJ94671.1, EGC94003.1, ZP_(—)08362542.1, YP_(—)002381459.1, AAN78852.1, NP_(—)752308.2, ZP_(—)07173894.1, ZP_(—)08357265.1, ZP_(—)08382276.1, ZP_(—)02902298.1, ZP_(—)04560694.1, ZP_(—)06354226.1, CBY94356.1, NP_(—)459307.1, EGE28353.1, ZP_(—)04657138.1, YP_(—)002225434.1, YP_(—)002635948.1, YP_(—)151638.1, ZP_(—)02663643.1, NP_(—)454921.1, YP_(—)004729161.1, YP_(—)215297.1, YP_(—)001454506.1, YP_(—)001571699.1, YP_(—)003363866.1, EGK30199.1, EGJ91900.1, EGK28208.1, ZP_(—)08497358.1, CBK85993.1, YP_(—)003611563.1, YP_(—)004592567.1, YP_(—)003441061.1, YP_(—)002240296.1, YP_(—)002917946.1, ZP_(—)06549304.1, ZP_(—)06017126.1, YP_(—)001333918.1, AAM28523.1, ZP_(—)08305363.1, YP_(—)001439185.1, EGL74026.1, YP_(—)001175495.1, ZP_(—)05968792.1, YP_(—)003209204.1, YP_(—)003943022.1, YP_(—)004499335.1, ZP_(—)06191708.1, YP_(—)001477183.1, ZP_(—)07951567.1, YP_(—)003740265.1, NP_(—)668276.1, ZP_(—)04637564.1, ZP_(—)04631714.1, CBY26031.1, YP_(—)004297237.1, YP_(—)001007400.1, ZP_(—)04625511.1, YP_(—)069424.1, ZP_(—)04616432.1, ZP_(—)04639135.1, YP_(—)001871363.1, ZP_(—)04620883.1, ZP_(—)06636999.1, ZP_(—)07377275.1, YP_(—)003929932.1, YP_(—)001722031.1, ZP_(—)04614013.1, ZP_(—)04628476.1, YP_(—)003713213.1, YP_(—)003530236.1, CBX79727.1, YP_(—)004114694.1, YP_(—)001908526.1, ADP11689.1, YP_(—)002649711.1, YP_(—)003469212.1, YP_(—)003519171.1, YP_(—)051564.1, ZP_(—)03833764.1, ZP_(—)03827249.1, NP_(—)928504.1, YP_(—)004211704.1, ZP_(—)07681706.1, YP_(—)003018849.1, YP_(—)003260788.1, YP_(—)003042091.1, ZP_(—)05973896.1, ZP_(—)03317495.1, ZP_(—)02958330.2, EFW60358.1, EGI98786.1, ZP_(—)06127315.2, YP_(—)002150121.1, ZP_(—)03842196.1, YP_(—)003884303.1, YP_(—)003003248.1, YP_(—)003334792.1, ZP_(—)03379559.1, CBA73629.1, YP_(—)002986552.1, ZP_(—)06538530.1, ZP_(—)01258771.1, ZP_(—)04921840.1, ZP_(—)06180371.1, ZP_(—)08308836.1, ZP_(—)06174994.1, YP_(—)001446380.1, ZP_(—)01237449.1, ZP_(—)01161468.1, ZP_(—)01222040.1, ZP_(—)06038476.1, ZP_(—)05925639.1, ZP_(—)06154677.1, ZP_(—)02195704.1, ZP_(—)01989646.1, ZP_(—)01868523.1, YP_(—)131060.1, ZP_(—)05722161.1, ZP_(—)05716057.1, NP_(—)798668.1, EGF45205.1, ZP_(—)05120764.1, EGR07881.1, ZP_(—)08100412.1, ZP_(—)04919383.1, ZP_(—)06054287.1, YP_(—)002156761.1, YP_(—)205315.2, ZP_(—)04961417.1, ZP_(—)06050299.1, ZP_(—)08103013.1, ZP_(—)01949008.1, NP_(—)231862.1, AEA79156.1, ZP_(—)06081122.1, ZP_(—)04418155.1, YP_(—)001217747.1, ZP_(—)04413631.1, NP_(—)935312.1, ZP_(—)01977990.1, NP_(—)760770.1, YP_(—)004188005.1, YP_(—)002810906.1, ZP_(—)05884155.1, ZP_(—)05946273.1, ZP_(—)01065180.1, ZP_(—)01815735.1, YP_(—)002417909.1, YP_(—)002263750.1, YP_(—)856109.1, ZP_(—)07744057.1, ZP_(—)08520214.1, ZP_(—)06034047.1, YP_(—)004565576.1, ZP_(—)05881167.1, ZP_(—)00991316.1, YP_(—)734276.1, ADT86286.1, YP_(—)001142550.1, YP_(—)869958.1, ZP_(—)08566610.1, ZP_(—)05876732.1, YP_(—)001366225.1, YP_(—)001094233.1, ADV54653.1, YP_(—)963612.1, YP_(—)738268.1, YP_(—)001502248.1, YP_(—)004391846.1, YP_(—)002311644.1, YP_(—)002358241.1, YP_(—)001050670.1, ZP_(—)07390237.1, YP_(—)001674114.1, YP_(—)001554497.1, NP_(—)718122.1, YP_(—)001760976.1, YP_(—)927745.1, YP_(—)562771.1, YP_(—)003557130.1, ZP_(—)02159449.1, YP_(—)003913548.1, YP_(—)001473736.1, YP_(—)750554.1, ZP_(—)01897495.1, YP_(—)268985.1, ZP_(—)01042474.1, ZP_(—)08570996.1, YP_(—)004427315.1, ZP_(—)07010199.1, YP_(—)156047.1, ZP_(—)07097521.1, YP_(—)004467113.1, ZP_(—)01614110.1, YP_(—)340459.1, YP_(—)004434754.1, YP_(—)662062.1, YP_(—)004068195.1, ZP_(—)08409704.1, ZP_(—)08622396.1, ZP_(—)01135962.1, ZP_(—)03560927.1, ZP_(—)04716612.1, EGB41427.1, EGP48304.1, EFV84045.1, ZP_(—)08505249.1, ZP_(—)06688896.1, YP_(—)003980530.1, YP_(—)003168652.1, YP_(—)003146346.1, YP_(—)001250478.1, YP_(—)095752.1, YP_(—)124009.1, CBW99992.1, YP_(—)284763.1, YP_(—)127029.1, YP_(—)746940.1, ZP_(—)07663653.1, ZP_(—)03349444.1, YP_(—)002354470.1, YP_(—)004145615.1, YP_(—)003524477.1, ZP_(—)03698069.1, YP_(—)003376672.1, ZP_(—)06188282.1, EFW81359.1, EGH83675.1, EGH67821.1, EFW83732.1, YP_(—)273865.1, NP_(—)902393.1, ZP_(—)06457469.1, EGH99235.1, ZP_(—)03397893.1, ZP_(—)07004262.1, ZP_(—)06732661.1, ZP_(—)07263971.1, EGH75297.1, NP_(—)888341.1, EGH31566.1, EGH45251.1, NP_(—)643363.1, EGH24154.1, EGH92666.1, EGH73945.1, EGH12424.1, NP_(—)793629.1, ZP_(—)06705890.1, YP_(—)234714.1, EGH62932.1, EGH52925.1, ZP_(—)01126966.1, NP_(—)841588.1, ZP_(—)05109483.1, YP_(—)003847638.1, YP_(—)004294524.1, ZP_(—)02244088.1, NP_(—)884586.1, ZP_(—)08176463.1, ZP_(—)04588788.1, YP_(—)450732.1, ZP_(—)08185386.1, YP_(—)001914265.1, YP_(—)003527565.1, YP_(—)004696148.1, NP_(—)638218.1, ZP_(—)05046817.1, YP_(—)343737.1, ZP_(—)07652844.1, YP_(—)004227922.1, YP_(—)364921.1, YP_(—)001632020.1, NP_(—)744048.1, YP_(—)001898007.1, YP_(—)003145987.1, YP_(—)558241.1, YP_(—)410795.1, YP_(—)001895310.1, YP_(—)002980410.1, ZP_(—)06841648.1, YP_(—)258889.1, YP_(—)931967.1, YP_(—)003760619.1, YP_(—)002029446.1, YP_(—)004474743.1, YP_(—)158312.1, YP_(—)004380764.1, YP_(—)001973352.1, CBJ39115.1, YP_(—)349912.1, YP_(—)003753442.1, ZP_(—)05135288.1, YP_(—)004700980.1, YP_(—)927690.1, YP_(—)001269130.1, YP_(—)742956.1, ADR61321.1, YP_(—)001347709.1, YP_(—)004355482.1, YP_(—)003907207.1, NP_(—)251505.1, ZP_(—)04929120.1, NP_(—)518658.1, YP_(—)002871500.1, ZP_(—)01451059.1, EGM21899.1, YP_(—)001187411.1, ZP_(—)08570514.1, ZP_(—)07794119.1, YP_(—)004391835.1, YP_(—)002256385.1, ZP_(—)07774414.1, YP_(—)855885.1, YP_(—)563120.1, YP_(—)001172167.1, YP_(—)004713921.1, ZP_(—)08138366.1, AEA83572.1, YP_(—)003746704.1, ZP_(—)08521441.1, ZP_(—)05061205.1, YP_(—)001667709.1, YP_(—)750573.1, YP_(—)607261.1, ZP_(—)05118288.1, YP_(—)002311716.1, NP_(—)718079.1, YP_(—)003777020.1, ZP_(—)06052248.1, ZP_(—)00943163.1, ZP_(—)08309312.1, AEG70141.1, YP_(—)001748377.1, YP_(—)001857928.1, YP_(—)001094176.1, YP_(—)003604813.1, ZP_(—)01947893.1, in particular EFW81359.1, EGH83675.1, EGH67821.1, EFW83732.1, YP_(—)273865.1, ZP_(—)06457469.1, EGH99235.1, ZP_(—)03397893.1, ZP_(—)07004262.1, ZP_(—)07263971.1, EGH75297.1, EGH31566.1, EGH45251.1, EGH24154.1, EGH92666.1, EGH73945.1, EGH12424.1, NP_(—)793629.1, YP_(—)234714.1, EGH62932.1, EGH52925.1, ZP_(—)04588788.1, NP_(—)744048.1, YP_(—)258889.1, YP_(—)004474743.1, YP_(—)004380764.1, YP_(—)349912.1, YP_(—)004700980.1, YP_(—)001269130.1, ADR61321.1, YP_(—)001347709.1, YP_(—)004355482.1, NP_(—)251505.1, ZP_(—)04929120.1, YP_(—)002871500.1, EGM21899.1, YP_(—)001187411.1, ZP_(—)07794119.1, ZP_(—)07774414.1, YP_(—)001172167.1, YP_(—)004713921.1, ZP_(—)08138366.1, AEA83572.1, YP_(—)001667709.1, YP_(—)607261.1, YP_(—)001748377.1, YP_(—)260045.1, YP_(—)002873091.1, ZP_(—)07775826.1, CAC34855.1, EGH11916.1, ZP_(—)05641615.1, ZP_(—)06480669.1, ZP_(—)06480668.1, ZP_(—)05641616.1, ZP_(—)06492823.1, ZP_(—)06492821.1, EGH11920.1, EGH25319.1, ZP_(—)06492824.1, ADX52254.1, AP_(—)000876.1, ZP_(—)08341828.1, YP_(—)002291517.1, YP_(—)003227327.1, YP_(—)001461409.1, AEG35025.1, YP_(—)002385739.1, ZP_(—)08352177.1, ZP_(—)03070250.1, ZP_(—)08367389.1, CBI99746.1, ZP_(—)06660773.1, ZP_(—)08372569.1, YP_(—)003497883.1, ACI71032.1, YP_(—)002406464.1, EGB79412.1, EFZ76765.1, ZP_(—)07145000.1, ZP_(—)07151031.1, EFZ56676.1, ZP_(—)06656148.1, EGB35012.1, EGB71054.1, ZP_(—)07183316.1, YP_(—)002396328.1, YP_(—)002327805.1, ZP_(—)03027602.1, AAG54546.1, YP_(—)001742341.1, ABE05764.1, EFX12717.1, ACI71029.1, NP_(—)285938.2, ZP_(—)07120505.1, YP_(—)539295.2, ZP_(—)03049609.1, ZP_(—)06652178.1, ABI99723.1, EGB60663.1, EFW71911.1, EGH38574.1, YP_(—)668186.1, ZP_(—)02801146.2, ZP_(—)08346491.1, ZP_(—)08362542.1, AAN78852.1, NP_(—)752308.2, ZP_(—)07173894.1, ZP_(—)08357265.1, ZP_(—)08382276.1, AAM28523.1, ZP_(—)07097521.1, EGB41427.1, EGB41426.1, BAA07583.1, ZP_(—)07100038.1, CAX20347.1 and particularly preferably NP_(—)744048.1, YP_(—)004700980.1, YP_(—)001269130.1, ADR61321.1, YP_(—)001667709.1, YP_(—)001748377.1, YP_(—)258889.1, YP_(—)349912.1, YP_(—)002871500.1, ZP_(—)07774414.1, YP_(—)260045.1, YP_(—)002873091.1, ZP_(—)07775826.1, CAC34855.1, YP_(—)001172167.1, YP_(—)004713921.1, AEA83572.1, AP_(—)000876.1, BAA07583.1, ZP_(—)07594808.1. and proteins with a polypeptide sequence wherein up to 60%, preferably up to 25%, particularly preferably up to 15%, in particular up to 10, 9, 8, 7, 6, 5, 4, 3, 2 or 1% of the amino acid residues compared to the aforementioned reference sequences are modified by deletion, insertion, substitution or a combination thereof and which still possess at least 50%, preferably 65%, particularly preferably 80%, in particular more than 90% of the activity of the protein with the corresponding, aforementioned reference sequence, wherein 100% activity of the reference protein is understood to mean the increasing of the activity of the cells used as a biocatalyst, i.e. the quantity of substance converted per unit time based on the cell quantity used (units per gram cell dry weight [U/g CDW]) in comparison to the activity of the biocatalyst in the absence of the reference protein, wherein the activity in this connection and in connection with the determination of the activity of the enzyme E_(b) in general is understood to mean in particular the oxidation of dodecanoyl-CoA thioesters to 2-dodecenoyl-CoA thioesters.

Specific Enzymes E_(c)

It is also preferable according to the invention that in the cells according to the invention the enzyme E_(c) is one which comprises sequences selected from:

YP_(—)003571780.1, YP_(—)445820.1, YP_(—)634556.1, YP_(—)004665862.1, ZP_(—)01461690.1, YP_(—)921666.1, YP_(—)002778910.1, ZP_(—)08550394.1, YP_(—)003384289.1, YP_(—)001195727.1, YP_(—)702012.1, ZP_(—)04384437.1, YP_(—)002765110.1, ZP_(—)04996322.1, ZP_(—)08195144.1, ZP_(—)04700546.1, YP_(—)954595.1, YP_(—)004736804.1, ADW07059.1, YP_(—)001827916.1, ZP_(—)04691466.1, YP_(—)001109453.1, ZP_(—)08240125.1, YP_(—)003272226.1, YP_(—)004053469.1, ZP_(—)06272176.1, YP_(—)004491616.1, YP_(—)001133991.1, YP_(—)001071715.1, YP_(—)290295.1, YP_(—)003193744.1, YP_(—)001704317.1, YP_(—)004008413.1, YP_(—)004655806.1, YP_(—)640598.1, ZP_(—)08153802.1, ZP_(—)00995173.1, ZP_(—)05225674.1, YP_(—)888747.1, YP_(—)003114111.1, YP_(—)004522832.1, ZP_(—)06848773.1, ZP_(—)08203814.1, YP_(—)001851901.1, EGO40578.1, YP_(—)003134974.1, ZP_(—)07282448.1, YP_(—)003770185.1, YP_(—)881295.1, YP_(—)004336131.1, NP_(—)961035.1, YP_(—)004164861.1, YP_(—)003681133.1, ZP_(—)04749633.1, ZP_(—)07718288.1, ZP_(—)01201898.1, YP_(—)004223976.1, YP_(—)118690.1, YP_(—)905275.1, BAE47462.1, YP_(—)831622.1, YP_(—)003407476.1, ZP_(—)01129477.1, YP_(—)003645654.1, YP_(—)004454693.1, YP_(—)002487953.1, YP_(—)004084231.1, YP_(—)003836912.1, YP_(—)004241154.1, ZP_(—)07706098.1, YP_(—)001855531.1, ZP_(—)08124588.1, YP_(—)947882.1, BAE47461.1, YP_(—)003327670.1, YP_(—)001363757.1, YP_(—)004601796.1, YP_(—)001625220.1, YP_(—)003638017.1, ZP_(—)06501585.1, YP_(—)004404736.1, YP_(—)062974.1, YP_(—)002957230.1, YP_(—)003316209.1, YP_(—)003149881.1, YP_(—)001221553.1, YP_(—)003162313.1, ZP_(—)03978917.1, YP_(—)001708860.1, ZP_(—)05912043.1, ZP_(—)06806059.1, YP_(—)003155732.1, YP_(—)002835700.1, YP_(—)003916799.1, ZP_(—)03936415.1, ZP_(—)07090640.1, ZP_(—)08516453.1, AAB97825.1, YP_(—)004541029.1, YP_(—)004606508.1, YP_(—)001801238.1, ZP_(—)07989876.1, YP_(—)004761186.1, YP_(—)002883572.1, ZP_(—)08023616.1, ZP_(—)05847263.1, YP_(—)251740.1, ZP_(—)03394212.1, YP_(—)001107648.1, YP_(—)002872770.1, YP_(—)001821654.1, ZP_(—)08233739.1, AAD12170.1, ZP_(—)08215859.1, AAD40800.1, ZP_(—)05005905.1, ADW07311.1, YP_(—)348592.1, NP_(—)824883.1, NP_(—)627459.1, YP_(—)001828149.1, ZP_(—)05525554.1, ZP_(—)08240364.1, ZP_(—)07299658.1, ZP_(—)06582153.1, ZP_(—)06921827.1, ZP_(—)04703961.1, BAJ27090.1, ZP_(—)06592678.1, ZP_(—)04691265.1, YP_(—)001751500.1, BAJ31579.1, preferably YP_(—)003571780.1, YP_(—)445820.1, YP_(—)634556.1, YP_(—)004665862.1, ZP_(—)01461690.1, YP_(—)921666.1, YP_(—)002778910.1, ZP_(—)08550394.1, YP_(—)003384289.1, YP_(—)001195727.1, YP_(—)702012.1, ZP_(—)04384437.1, YP_(—)002765110.1, ZP_(—)04996322.1, ZP_(—)08195144.1, ZP_(—)04700546.1, YP_(—)954595.1, YP_(—)004736804.1, ADW07059.1, YP_(—)001827916.1, ZP_(—)04691466.1, YP_(—)001109453.1, ZP_(—)08240125.1, YP_(—)003272226.1, YP_(—)004053469.1, ZP_(—)06272176.1, YP_(—)004491616.1, YP_(—)001133991.1, YP_(—)001071715.1, YP_(—)290295.1, YP_(—)003193744.1, YP_(—)001704317.1, YP_(—)004008413.1, YP_(—)004655806.1, YP_(—)640598.1, ZP_(—)08153802.1, ZP_(—)00995173.1, ZP_(—)05225674.1, YP_(—)888747.1, YP_(—)003114111.1, YP_(—)004522832.1, ZP_(—)06848773.1, ZP_(—)08203814.1, YP_(—)001851901.1, EGO40578.1, YP_(—)003134974.1, ZP_(—)07282448.1, YP_(—)003770185.1, YP_(—)881295.1, YP_(—)004336131.1, NP_(—)961035.1, YP_(—)004164861.1, YP_(—)003681133.1, ZP_(—)04749633.1, ZP_(—)07718288.1, ZP_(—)01201898.1, YP_(—)004223976.1, YP_(—)118690.1, YP_(—)905275.1, BAE47462.1, YP_(—)831622.1, YP_(—)003407476.1, ZP_(—)01129477.1, YP_(—)003645654.1, YP_(—)004454693.1, YP_(—)002487953.1, YP_(—)004084231.1, YP_(—)003836912.1, YP_(—)004241154.1, ZP_(—)07706098.1, YP_(—)001855531.1, ZP_(—)08124588.1, YP_(—)947882.1, BAE47461.1, YP_(—)003327670.1, YP_(—)001363757.1, YP_(—)004601796.1, YP_(—)001625220.1, YP_(—)003638017.1, ZP_(—)06501585.1, YP_(—)004404736.1, YP_(—)062974.1, YP_(—)002957230.1, YP_(—)003316209.1, YP_(—)003149881.1, YP_(—)001221553.1, YP_(—)003162313.1, ZP_(—)03978917.1, YP_(—)001708860.1, ZP_(—)05912043.1, ZP_(—)06806059.1, YP_(—)003155732.1, YP_(—)002835700.1, YP_(—)003916799.1, ZP_(—)03936415.1, ZP_(—)07090640.1, ZP_(—)08516453.1, AAB97825.1, YP_(—)004541029.1, YP_(—)004606508.1, YP_(—)001801238.1, ZP_(—)07989876.1, YP_(—)004761186.1, YP_(—)002883572.1, ZP_(—)08023616.1, ZP_(—)05847263.1, YP_(—)251740.1, and particularly preferably YP_(—)002835700.1, ZP_(—)03936415.1, BAE47461.1, YP_(—)001801238.1, ZP_(—)03978917.1, ZP_(—)03394212.1, ZP_(—)05847263.1, ZP_(—)08516453.1, YP_(—)004606508.1, YP_(—)251740.1, ZP_(—)07090640.1, ZP_(—)07989876.1, YP_(—)004761186.1, and proteins with a polypeptide sequence wherein up to 60%, preferably up to 25%, particularly preferably up to 15%, in particular up to 10, 9, 8, 7, 6, 5, 4, 3, 2 or 1% of the amino acid residues compared to the aforementioned reference sequences are modified by deletion, insertion, substitution or a combination thereof and which still possess at least 50%, preferably 65%, particularly preferably 80%, in particular more than 90% of the activity of the protein with the corresponding, aforementioned reference sequence, wherein 100% activity of the reference protein is understood to mean the increasing of the activity of the cells used as a biocatalyst, i.e. the quantity of substance converted per unit time based on the cell quantity used (units per gram cell dry weight [U/g CDW]) in comparison to the activity of the biocatalyst in the absence of the reference protein, wherein the activity in this connection and in connection with the determination of the activity of the enzyme E_(c) in general is understood to mean in particular the oxidation of dodecanoyl-CoA thioesters to 2-dodecenoyl-CoA thioesters.

Specific Enzymes E_(d) and E_(e)

It is also preferable according to the invention that in the cells according to the invention the enzyme E_(d) or E_(e) is one which comprises sequences selected from:

ZP_(—)07164313.1, NP_(—)418288.1, YP_(—)003231641.1, EGM59778.1, EFZ53307.1, AAA23750.1, ZP_(—)07192215.1, YP_(—)001460638.1, YP_(—)001727088.1, EGK16564.1, ZP_(—)08380619.1, ZP_(—)07136310.1, CAB40809.1, NP_(—)839030.1, ZP_(—)07690617.1, EGC97039.1, ZP_(—)07103516.1, ZP_(—)03027888.1, ZP_(—)07121980.1, YP_(—)002414996.1, EGP22873.1, EGJ82677.1, EGB59499.1, ZP_(—)07118761.1, YP_(—)002409078.1, YP_(—)002295407.1, EGE62412.1, EGB69560.1, ZP_(—)06655948.1, ZP_(—)06664574.1, ZP_(—)03070699.1, ZP_(—)07145404.1, ZP_(—)08376058.1, EGB85466.1, ZP_(—)07189176.1, ZP_(—)02999920.1, ZP_(—)08356523.1, ZP_(—)06659936.1, ZP_(—)07139396.1, YP_(—)001746178.1, YP_(—)002384700.1, ZP_(—)07098889.1, CBG37051.1, ZP_(—)04873109.1, CBJ03626.1, ZP_(—)08366395.1, ZP_(—)03066301.1, BAI57243.1, YP_(—)001465330.1, YP_(—)405325.1, NP_(—)312801.1, EGI89589.1, EGC09628.1, EFW73050.1, ZP_(—)07221474.1, EGB39932.1, EFW72281.1, ZP_(—)07154547.1, YP_(—)002331616.1, EGB76756.1, EFZ75005.1, ZP_(—)07449248.1, NP_(—)756652.2, ZP_(—)04006347.1, NP_(—)290476.1, EGH36687.1, YP_(—)671920.1, ZP_(—)08350773.1, EGC05062.1, ZP_(—)07174622.1, CAP78309.1, ZP_(—)08361145.1, YP_(—)002400350.1, ZP_(—)08386169.1, EFU60028.1, ZP_(—)02904283.1, YP_(—)859447.1, YP_(—)543379.2, NP_(—)462868.1, ZP_(—)02663494.1, ACY91152.1, ZP_(—)03221347.1, YP_(—)001591071.1, YP_(—)002639596.1, EFY10009.1, ZP_(—)04656823.1, ZP_(—)03213459.1, ZP_(—)02701437.1, ZP_(—)02347126.1, YP_(—)002217909.1, ZP_(—)02658976.1, YP_(—)002245833.1, YP_(—)002228260.1, YP_(—)001451793.1, EGE35935.1, YP_(—)002047992.1, ZP_(—)02834645.1, ZP_(—)02669606.1, YP_(—)001572623.1, ZP_(—)03075319.1, YP_(—)002148908.1, YP_(—)004591813.1, ZP_(—)03163685.1, YP_(—)002043211.1, NP_(—)457769.1, YP_(—)003367347.1, YP_(—)004732313.1, ZP_(—)06546517.1, ZP_(—)08495782.1, ZP_(—)04558441.1, YP_(—)002241091.1, ZP_(—)06354348.2, ZP_(—)06552493.1, YP_(—)001337975.1, YP_(—)001178655.1, CBK87780.1, ZP_(—)05970964.1, ZP_(—)06014071.1, YP_(—)002917176.1, YP_(—)152910.1, Q9F0Y7.1, ZP_(—)08302760.1, YP_(—)003615422.1, YP_(—)003943709.1, EGI93642.1, YP_(—)001439747.1, YP_(—)003208640.1, YP_(—)001476499.1, ZP_(—)06638309.1, YP_(—)004498688.1, YP_(—)004296470.1, ZP_(—)06192594.1, YP_(—)001004653.1, ZP_(—)04634366.1, CBY29055.1, ZP_(—)04641538.1, ZP_(—)04628383.1, ZP_(—)04620754.1, ZP_(—)04624649.1, YP_(—)003739635.1, ZP_(—)07953302.1, YP_(—)001399280.1, NP_(—)667802.1, YP_(—)068813.1, ADV97208.1, ZP_(—)04637125.1, YP_(—)003019595.1, YP_(—)048335.1, ZP_(—)04612255.1, ZP_(—)03831342.1, ZP_(—)03827989.1, YP_(—)003261565.1, ZP_(—)04616540.1, EFW54755.1, YP_(—)004214864.1, BAK13441.1, YP_(—)003518496.1, YP_(—)003933023.1, ZP_(—)07380063.1, YP_(—)003042702.1, YP_(—)003713991.1, YP_(—)003466462.1, YP_(—)004114076.1, YP_(—)001906200.1, NP_(—)931575.1, EGK17810.1, CBX79037.1, YP_(—)003529581.1, ZP_(—)06937250.1, YP_(—)002647270.1, ADP11112.1, ZP_(—)05974166.1, ZP_(—)03318464.1, ZP_(—)02958886.1, YP_(—)003331802.1, ZP_(—)06125606.1, YP_(—)003006180.1, YP_(—)003885045.1, YP_(—)128321.1, ZP_(—)01236908.1, ZP_(—)01161145.1, YP_(—)002989323.1, YP_(—)002154796.1, YP_(—)203408.1, ZP_(—)08310903.1, YP_(—)002264299.1, ZP_(—)01221704.1, ZP_(—)06050960.1, ZP_(—)03841335.1, ZP_(—)05883431.1, YP_(—)002153226.1, ADT85583.1, ZP_(—)05879947.1, ZP_(—)04923724.1, ZP_(—)01262258.1, ZP_(—)06179383.1, ZP_(—)05883853.1, EGF42158.1, ZP_(—)01957954.1, ZP_(—)08101926.1, ZP_(—)06177050.1, NP_(—)759944.1, NP_(—)796409.1, ZP_(—)04419618.1, ZP_(—)01987794.1, ZP_(—)05121182.1, YP_(—)001443702.1, ZP_(—)01948571.1, ZP_(—)01682057.1, ZP_(—)04405432.1, NP_(—)232384.1, ZP_(—)04409574.1, ZP_(—)01870127.1, NP_(—)932822.1, ZP_(—)06943917.1, EGR05147.1, ZP_(—)04961951.1, EGR10674.1, ZP_(—)04414292.1, ZP_(—)05718020.1, ZP_(—)08098153.1, ZP_(—)05719938.1, ZP_(—)03356468.1, ZP_(—)07742015.1, YP_(—)004564872.1, ZP_(—)01979859.1, ZP_(—)00992843.1, ZP_(—)05927571.1, ZP_(—)01065523.1, YP_(—)002415749.1, ZP_(—)01815881.1, ZP_(—)02196043.1, YP_(—)001143922.1, ZP_(—)08518445.1, ZP_(—)06156529.1, YP_(—)004394586.1, ZP_(—)01900693.1, YP_(—)854676.1, ZP_(—)05943242.1, CBA71812.1, ZP_(—)01991723.1, YP_(—)001092151.1, YP_(—)001672251.1, YP_(—)961420.1, YP_(—)003554801.1, YP_(—)003911300.1, ADV52504.1, YP_(—)001364252.1, YP_(—)001552462.1, ZP_(—)07394327.1, YP_(—)001048426.1, YP_(—)002355987.1, ZP_(—)02158912.1, ABE53312.1, YP_(—)561035.2, YP_(—)748714.1, ZP_(—)01135242.1, NP_(—)715663.1, YP_(—)732157.1, YP_(—)867675.1, YP_(—)736079.1, YP_(—)001758417.1, YP_(—)001499882.1, YP_(—)004436299.1, YP_(—)659787.1, ZP_(—)08620874.1, YP_(—)002309470.1, CBW44433.1, ZP_(—)08568624.1, YP_(—)958423.1, YP_(—)925914.1, YP_(—)001471764.1, ZP_(—)01165107.1, ZP_(—)04717156.1, ZP_(—)01042072.1, ZP_(—)08568929.1, YP_(—)004468425.1, ZP_(—)01614054.1, EGH60623.1, NP_(—)744285.1, ZP_(—)04587907.1, EGH84450.1, YP_(—)609235.1, Q93Q12.1, ZP_(—)07263341.1, YP_(—)004425808.1, EGH10831.1, ZP_(—)08142928.1, YP_(—)435877.1, YP_(—)004701152.1, ADR61111.1, EGH72107.1, ZP_(—)07255969.1, EGH76237.1, YP_(—)154404.1, EGH66371.1, ZP_(—)07005687.1, YP_(—)001268914.1, ZP_(—)03397164.1, YP_(—)267151.1, EGH45982.1, NP_(—)793297.1, YP_(—)236360.1, YP_(—)001667915.1, EGH29726.1, ZP_(—)03561781.1, YP_(—)275370.1, ABP88736.1, ZP_(—)06458302.1, YP_(—)001748526.1, YP_(—)002871195.1, ZP_(—)06478839.1, EGH95845.1, YP_(—)004067126.1, EGH21541.1, ZP_(—)05638744.1, Q9AHY3.2, YP_(—)338568.1, ZP_(—)06078672.1, YP_(—)004352961.1, ZP_(—)01892768.1, ZP_(—)06040413.1, YP_(—)349607.1, YP_(—)259059.1, ZP_(—)08409548.1, ADP97276.1, YP_(—)004713990.1, YP_(—)003626258.1, P28793.1, YP_(—)001172246.1, YP_(—)003810247.1, YP_(—)004313957.1, EGE21928.1, EGE19309.1, EGE13641.1, ZP_(—)08462037.1, EGE13529.1, ZP_(—)06034789.1, EGE12165.1, AEA83639.1, YP_(—)002798635.1, ZP_(—)01306165.1, YP_(—)004474976.1, ZP_(—)01739261.1, NP_(—)251704.1, ACP17923.1, YP_(—)004379416.1, YP_(—)001280990.1, YP_(—)003145204.1, YP_(—)001347517.1, ZP_(—)06877966.1, YP_(—)001187076.1, ZP_(—)08638729.1, YP_(—)001340441.1, ZP_(—)05128804.1, YP_(—)003896827.1, YP_(—)003073151.1, ZP_(—)05096745.1, ZP_(—)01103278.1, YP_(—)693372.1, ZP_(—)01366482.1, ZP_(—)05619303.1, ZP_(—)08328596.1, ZP_(—)05042935.1, YP_(—)574439.1, ZP_(—)01074264.1, YP_(—)004482149.1, YP_(—)045111.1, YP_(—)265216.1, ZP_(—)05362445.1, YP_(—)001715228.1, YP_(—)001844981.1, YP_(—)001708314.1, YP_(—)581488.1, ADY83798.1, ZP_(—)06692406.1, YP_(—)003733838.1, ZP_(—)05824704.1, ZP_(—)06058514.1, ZP_(—)08554004.1, ZP_(—)06068411.1, ZP_(—)06067277.1, ZP_(—)06726497.1, ADX01983.1, ZP_(—)03822268.1, ZP_(—)03347927.1, ZP_(—)01116792.1, YP_(—)527079.1, ZP_(—)06063435.1, ZP_(—)06534677.1, ZP_(—)01219812.1, ZP_(—)03347768.1, YP_(—)002798829.1, ZP_(—)07774142.1, YP_(—)003557881.1, ZP_(—)06157092.1, ZP_(—)01223872.1, ZP_(—)05946076.1, ZP_(—)06499586.1, YP_(—)003451185.1, YP_(—)002361722.1, YP_(—)003266103.1, YP_(—)285556.2, AAZ47086.1, NP_(—)968701.1, ZP_(—)06936670.1, ZP_(—)03805048.1, YP_(—)943922.1, ZP_(—)01217009.1, ADT87675.1, ZP_(—)05877956.1, ZP_(—)03355309.1, ZP_(—)05885304.1, EGK17811.1, ZP_(—)05944972.1, ZP_(—)05119053.1, ZP_(—)06039619.1, ZP_(—)05716842.1, ZP_(—)05721090.1, ZP_(—)06079171.1, ZP_(—)06033023.1, ZP_(—)08098475.1, ZP_(—)08104504.1, ZP_(—)06048048.1, ZP_(—)01677170.1, ZP_(—)01681193.1, NP_(—)230692.2, ZP_(—)05926205.1, ZP_(—)05881372.1, ZP_(—)01975051.1, ZP_(—)04412573.1, ZP_(—)01977591.1, ZP_(—)04415061.1, ZP_(—)06048243.1, YP_(—)742943.1, ZP_(—)04962518.1, ZP_(—)01955504.1, ZP_(—)07741831.1, EGK33112.1, ZP_(—)01980800.1, CBW26643.1, EGQ99075.1, ZP_(—)03561616.1, ZP_(—)06155835.1, ZP_(—)01613403.1, YP_(—)003147156.1, ZP_(—)01866421.1, ZP_(—)08569601.1, YP_(—)004068133.1, ZP_(—)01992793.1, YP_(—)003760621.1, NP_(—)760849.1, NP_(—)935233.1, YP_(—)661240.1, CBA76402.1, YP_(—)003527567.1, ZP_(—)05071916.1, YP_(—)155382.1, ZP_(—)08567109.1, ZP_(—)08410490.1, YP_(—)002357526.1, YP_(—)001473368.1, ZP_(—)05061211.1, ZP_(—)08309062.1, ZP_(—)00990722.1, ZP_(—)01813160.1, YP_(—)343735.1, YP_(—)001366977.1, ZP_(—)07393465.1, YP_(—)002312436.1, ZP_(—)03805047.1, ZP_(—)04716066.1, ZP_(—)01043968.1, YP_(—)562538.1, ZP_(—)01064421.1, YP_(—)928042.1, YP_(—)002416486.1, YP_(—)962941.1, YP_(—)001051116.1, YP_(—)004467793.1, YP_(—)004434876.1, YP_(—)001183979.1, ZP_(—)01125518.1, YP_(—)001555281.1, ZP_(—)01900341.1, YP_(—)001459147.1, ADV54930.1, ZP_(—)06054161.1, YP_(—)001674882.1, YP_(—)001381324.1, ZP_(—)02158374.1, NP_(—)718651.1, YP_(—)737529.1, YP_(—)869101.1, ZP_(—)01258852.1, ZP_(—)05978956.1, ZP_(—)06179776.1, YP_(—)733543.1, ZP_(—)01989664.1, NP_(—)798587.1, EGF45285.1, ZP_(—)05908370.1, YP_(—)001502453.1, ZP_(—)06639387.1, YP_(—)003557654.1, ZP_(—)04921889.1, YP_(—)001436988.1, YP_(—)003468880.1, YP_(—)001761392.1, YP_(—)003267851.1, YP_(—)004730996.1, EGL72460.1, YP_(—)003742516.1, YP_(—)003258850.1, ZP_(—)01132697.1, ZP_(—)01987078.1, YP_(—)004392689.1, ZP_(—)06191156.1, YP_(—)002381996.1, ZP_(—)06176023.1, EGC06853.1, ZP_(—)07196084.1, NP_(—)754768.1, ZP_(—)02901855.1, ZP_(—)08620438.1, EGE30558.1, YP_(—)003211325.1, ZP_(—)03220131.1, YP_(—)217377.1, YP_(—)003940937.1, YP_(—)004669896.1, YP_(—)633521.1, YP_(—)002041652.1, NP_(—)456929.1, YP_(—)001446296.1, ZP_(—)02699767.1, YP_(—)001586838.1, YP_(—)751355.1, ZP_(—)08384609.1, YP_(—)002216460.1, A8GH86.2, ZP_(—)02667448.1, YP_(—)004595105.1, YP_(—)002408448.1, YP_(—)001479604.1, YP_(—)149790.1, NP_(—)461330.1, YP_(—)002227302.1, ZP_(—)07187886.1, ZP_(—)08374604.1, ZP_(—)02343362.1, ZP_(—)02683558.1, YP_(—)001141958.1, ZP_(—)02662473.1, ZP_(—)07151809.1, YP_(—)004211957.1, YP_(—)003366276.1, YP_(—)003713364.1, ZP_(—)03035287.1, ZP_(—)08364768.1, YP_(—)002413389.1, ZP_(—)07448710.1, ZP_(—)04656170.1, ZP_(—)02654823.1, ZP_(—)01222785.1, EGB63194.1, ZP_(—)08359459.1, YP_(—)002636921.1, YP_(—)002329984.1, YP_(—)001744544.1, CAP76837.1, EFZ73229.1, EFU57443.1, YP_(—)002398712.1, YP_(—)003018387.1, ZP_(—)08520753.1, YP_(—)541623.1, ZP_(—)02574174.1, ZP_(—)07144040.1, ZP_(—)08349090.1, CBG35413.1, ZP_(—)04562847.1, ZP_(—)02195785.1, ZP_(—)02773221.1, EGB40918.1, ZP_(—)03050715.1, ZP_(—)07787570.1, ZP_(—)03831301.1, YP_(—)003003682.1, ZP_(—)08354786.1, YP_(—)051168.1, YP_(—)002403607.1, AEE57458.1, YP_(—)856678.1, YP_(—)001177597.1, ZP_(—)06658276.1, NP_(—)288914.1, YP_(—)002392166.1, ZP_(—)06654274.1, ZP_(—)07102361.1, EGB72544.1, YP_(—)004501987.1, ZP_(—)03027319.1, YP_(—)670274.1, YP_(—)003913906.1, ZP_(—)07097669.1, YP_(—)001463687.1, BAI55757.1, ZP_(—)08553509.1, YP_(—)003500399.1, ZP_(—)07121648.1, ZP_(—)01235780.1, CBK87125.1, YP_(—)002293925.1, ZP_(—)05431367.1, YP_(—)129175.1, ZP_(—)03003629.1, YP_(—)002387809.1, ZP_(—)03043524.1, YP_(—)001569579.1, ZP_(—)05435840.1, ZP_(—)01464666.1, YP_(—)001724305.1, ZP_(—)03068335.1, CBJ01980.1, AEJ57562.1, NP_(—)416843.1, YP_(—)002920590.1, ZP_(—)03828462.1, EGM60943.1, ZP_(—)06351976.1, ZP_(—)05968584.1, EGK21055.1, YP_(—)003040254.1, NP_(—)708223.1, YP_(—)689824.1, ZP_(—)04625886.1, AEJ99232.1, ZP_(—)07135079.1, YP_(—)339488.1, ZP_(—)07247352.1, ZP_(—)07590743.1, ZP_(—)08303100.1, EFU96242.1, EFZ69715.1, YP_(—)001336370.1, YP_(—)001094550.1, ZP_(—)07679578.1, ZP_(—)06547779.1, EGI93593.1, YP_(—)003438264.1, YP_(—)003614165.1, YP_(—)408769.1, YP_(—)001881164.1, YP_(—)003655512.1, YP_(—)002237269.1, YP_(—)004116642.1, ZP_(—)03065203.1, ZP_(—)07951118.1, CAQ79951.1, AAZ26206.1, BAK12062.1, YP_(—)269853.2, NP_(—)930429.2, YP_(—)404102.1, ZP_(—)04620204.1, ZP_(—)08498986.1, YP_(—)001452041.1, ZP_(—)01159981.1, CAE15574.1, A1JK30.2, ZP_(—)04635573.1, ZP_(—)02904987.1, ZP_(—)02961182.1, YP_(—)001005598.1, ZP_(—)01301762.1, ZP_(—)06016509.1, CBY28037.1, ZP_(—)05060968.1, ZP_(—)04632512.1, YP_(—)002156637.1, YP_(—)002132807.1, Q5E3U1.2, YP_(—)205193.1, ZP_(—)04613435.1, ZP_(—)07380136.1, YP_(—)004299028.1, YP_(—)003334344.1, YP_(—)001610684.1, YP_(—)001720255.1, YP_(—)001400379.1, YP_(—)652007.1, NP_(—)668898.1, ZP_(—)04640314.1, ADV98116.1, ZP_(—)03840558.1, ZP_(—)07047543.1, ZP_(—)03320348.1, YP_(—)001681761.1, ZP_(—)04615169.1, ZP_(—)08182604.1, YP_(—)003520988.1, YP_(—)002151536.1, NP_(—)641653.1, ZP_(—)08188276.1, Q668V1.2, YP_(—)463621.1, ZP_(—)05032523.1, YP_(—)363100.1, YP_(—)002490860.1, YP_(—)071146.1, YP_(—)003527951.1, YP_(—)004615064.1, ZP_(—)06702935.1, YP_(—)003277339.1, ZP_(—)06729873.1, YP_(—)004552309.1, ZP_(—)08178119.1, YP_(—)558747.1, YP_(—)003059322.1, ZP_(—)04628689.1, ZP_(—)05043496.1, YP_(—)755774.1, NP_(—)106254.1, NP_(—)774461.1, YP_(—)004145058.1, NP_(—)636640.1, YP_(—)001411745.1 YP_(—)244043.1, YP_(—)003906899.1, ZP_(—)02151779.1, EFW54754.1, YP_(—)004147062.1, YP_(—)434583.1, ZP_(—)06862658.1, YP_(—)003559491.1, ZP_(—)07474361.1, ZP_(—)07478578.1, ZP_(—)03787298.1, ZP_(—)06840682.1, ZP_(—)05161835.1, ZP_(—)06794105.1, ZP_(—)05181908.1, ZP_(—)05174379.1, YP_(—)003883888.1, NP_(—)541475.1, NP_(—)949054.1, YP_(—)003931777.1, YP_(—)001993209.1, ZP_(—)06124668.1, YP_(—)001594738.1, ZP_(—)06070710.1, ZP_(—)06484372.1, YP_(—)002515449.1, YP_(—)001895558.1, YP_(—)002029364.1, ZP_(—)02891585.1, ZP_(—)04682672.1, YP_(—)003761433.1, YP_(—)004107983.1, YP_(—)223224.1, YP_(—)003812264.1, YP_(—)001622574.1, ZP_(—)05452320.1, YP_(—)002734532.1, YP_(—)001257739.1, YP_(—)001372564.1, ZP_(—)05137372.1, YP_(—)001973266.1, YP_(—)342869.1, NP_(—)699967.1, ZP_(—)05086267.1, ZP_(—)01736760.1, YP_(—)001914218.1, ZP_(—)05157647.1, YP_(—)485365.1, YP_(—)001926123.1, ZP_(—)05116437.1, ZP_(—)03544469.1, ZP_(—)08330383.1, ZP_(—)06491403.1, ZP_(—)01896167.1, ADP99705.1, ZP_(—)02883593.1, YP_(—)004228182.1, YP_(—)570677.1, ZP_(—)01225298.1, YP_(—)200487.1, YP_(—)002988196.1, ZP_(—)08269313.1, NP_(—)767800.1, YP_(—)001094989.1, ZP_(—)06065014.1, YP_(—)002981447.1, YP_(—)001260831.1, YP_(—)003817548.1, YP_(—)532099.1, ZP_(—)07676723.1, YP_(—)001242863.1, ZP_(—)02244047.1, YP_(—)982073.1, YP_(—)001899020.1, NP_(—)519880.1, ZP_(—)02379339.1, NP_(—)946171.1, ZP_(—)01615132.1, YP_(—)456953.1, ZP_(—)02168372.1, ZP_(—)08552434.1, CBJ37969.1, YP_(—)004418392.1, ZP_(—)02362492.1, YP_(—)004107339.1, YP_(—)001203133.1, ZP_(—)01546752.1, YP_(—)002974094.1, ZP_(—)02186892.1, YP_(—)001989920.1, YP_(—)002964466.1, ZP_(—)03265887.1, YP_(—)555553.1, CBA26305.1, ZP_(—)06728723.1, ZP_(—)07656835.1, ZP_(—)05620865.1, YP_(—)575713.1, YP_(—)001907090.1, YP_(—)002911224.1, YP_(—)047520.1, YP_(—)004688052.1, in particular EGH60623.1, NP_(—)744285.1, ZP_(—)04587907.1, EGH84450.1, YP_(—)609235.1, Q93Q12.1, ZP_(—)07263341.1, EGH10831.1, ZP_(—)08142928.1, YP_(—)004701152.1, ADR61111.1, EGH72107.1, ZP_(—)07255969.1, EGH76237.1, EGH66371.1, ZP_(—)07005687.1, YP_(—)001268914.1, ZP_(—)03397164.1, EGH45982.1, NP_(—)793297.1, YP_(—)236360.1, YP_(—)001667915.1, EGH29726.1, YP_(—)275370.1, ABP88736.1, ZP_(—)06458302.1, YP_(—)001748526.1, YP_(—)002871195.1, ZP_(—)06478839.1, EGH95845.1, EGH21541.1, ZP_(—)05638744.1, Q9AHY3.2, YP_(—)004352961.1, YP_(—)349607.1, YP_(—)259059.1, YP_(—)004713990.1, P28793.1, YP_(—)001172246.1, AEA83639.1, YP_(—)004474976.1, NP_(—)251704.1, ACP17923.1, YP_(—)004379416.1, YP_(—)001347517.1, ZP_(—)06877966.1, YP_(—)001187076.1, ZP_(—)01366482.1, ZP_(—)07774142.1, ZP_(—)06499586.1, YP_(—)791508.1, ZP_(—)07796310.1, NP_(—)250428.1, YP_(—)002441177.1, YP_(—)001348922.1, ZP_(—)06879352.1, AEA82038.1, YP_(—)001170648.1, YP_(—)004473370.1, YP_(—)004712521.1, YP_(—)004353314.1, ZP_(—)07164313.1, NP_(—)418288.1, YP_(—)003231641.1, AAA23750.1, ZP_(—)07192215.1, YP_(—)001460638.1, YP_(—)001727088.1, ZP_(—)08380619.1, ZP_(—)07136310.1, CAB40809.1, ZP_(—)07690617.1, ZP_(—)07103516.1, ZP_(—)03027888.1, ZP_(—)07121980.1, YP_(—)002414996.1, EGP22873.1, EGB59499.1, ZP_(—)07118761.1, YP_(—)002409078.1, YP_(—)002295407.1, EGE62412.1, EGB69560.1, ZP_(—)06655948.1, ZP_(—)06664574.1, ZP_(—)03070699.1, ZP_(—)07145404.1, ZP_(—)08376058.1, EGB85466.1, ZP_(—)07189176.1, ZP_(—)02999920.1, ZP_(—)08356523.1, ZP_(—)06659936.1, ZP_(—)07139396.1, YP_(—)001746178.1, ZP_(—)07098889.1, CBG37051.1, CBJ03626.1, ZP_(—)08366395.1, BAI57243.1, YP_(—)001465330.1, NP_(—)312801.1, EGC09628.1, EFW73050.1, ZP_(—)07221474.1, EGB39932.1, EFW72281.1, ZP_(—)07154547.1, YP_(—)002331616.1, EGB76756.1, EFZ75005.1, ZP_(—)07449248.1, NP_(—)756652.2, ZP_(—)04006347.1, NP_(—)290476.1, EGH36687.1, YP_(—)671920.1, ZP_(—)08350773.1, ZP_(—)07174622.1, CAP78309.1, ZP_(—)08361145.1, YP_(—)002400350.1, ZP_(—)08386169.1, EFU60028.1, YP_(—)859447.1, YP_(—)543379.2, ZP_(—)06937250.1, ZP_(—)06936670.1, YP_(—)001459147.1, ZP_(—)07196084.1, NP_(—)754768.1, ZP_(—)08384609.1, YP_(—)002408448.1, ZP_(—)07187886.1, ZP_(—)08374604.1, ZP_(—)07151809.1, ZP_(—)03035287.1, ZP_(—)08364768.1, YP_(—)002413389.1, ZP_(—)07448710.1, EGB63194.1, ZP_(—)08359459.1, YP_(—)002329984.1, YP_(—)001744544.1, CAP76837.1, EFZ73229.1, EFU57443.1, YP_(—)002398712.1, YP_(—)541623.1, ZP_(—)07144040.1, ZP_(—)08349090.1, CBG35413.1, ZP_(—)02773221.1, EGB40918.1, ZP_(—)03050715.1, ZP_(—)07787570.1, ZP_(—)08354786.1, YP_(—)002403607.1, AEE57458.1, ZP_(—)06658276.1, NP_(—)288914.1, YP_(—)002392166.1, ZP_(—)06654274.1, ZP_(—)07102361.1, EGB72544.1, ZP_(—)03027319.1, YP_(—)670274.1, ZP_(—)07097669.1, YP_(—)001463687.1, BAI55757.1, YP_(—)003500399.1, ZP_(—)07121648.1, YP_(—)002293925.1, ZP_(—)03003629.1, YP_(—)002387809.1, ZP_(—)03043524.1, YP_(—)001724305.1, ZP_(—)03068335.1, CBJ01980.1, AEJ57562.1, NP_(—)416843.1, ZP_(—)07135079.1, ZP_(—)07247352.1, ZP_(—)07590743.1, EFU96242.1, EFZ69715.1, and particularly preferably NP_(—)744285.1, YP_(—)004701152.1, ADR61111.1, YP_(—)001268914.1, YP_(—)001667915.1, ABP88736.1, YP_(—)001748526.1, Q9AHY3.2, YP_(—)004713990.1, YP_(—)001172246.1, AEA83639.1, AEA82038.1, YP_(—)001170648.1, YP_(—)004712521.1, YP_(—)002871195.1, YP_(—)349607.1, YP_(—)259059.1, ZP_(—)07774142.1, NP_(—)418288.1, NP_(—)416843.1, ZP_(—)07593201.1, ZP_(—)07590743.1, and proteins with a polypeptide sequence wherein up to 60%, preferably up to 25%, particularly preferably up to 15%, in particular up to 10, 9, 8, 7, 6, 5, 4, 3, 2 or 1% of the amino acid residues compared to the aforementioned reference sequences are modified by deletion, insertion, substitution or a combination thereof and which still possess at least 50%, preferably 65%, particularly preferably 80%, in particular more than 90% of the activity of the protein with the corresponding, aforementioned reference sequence, wherein 100% activity of the reference protein is understood to mean the increasing of the activity of the cells used as a biocatalyst, i.e. the quantity of substance converted per unit time based on the cell quantity used (units per gram cell dry weight [U/g CDW]) in comparison to the activity of the biocatalyst in the absence of the reference protein, wherein the activity in this connection and in connection with the determination of the activity of the enzyme E_(d) and E_(e) in general is understood to mean in particular the conversion of 2-dodecenoyl-CoA thioesters to 3-oxo-dodecanoyl-CoA thioesters.

Specific Enzymes E_(f)

It is also preferable according to the invention that in the cells according to the invention the enzyme E_(f) is one which comprises sequences selected from:

YP_(—)026272.1, YP_(—)002389323.1, EGB30581.1, YP_(—)001460637.1, YP_(—)001727089.1, CAB40810.1, EGK16565.1, NP_(—)709649.1, YP_(—)001882545.1, ZP_(—)08356522.1, ZP_(—)06664573.1, AAA67642.1, ADA76222.1, EGK17812.1, YP_(—)405326.1, YP_(—)003236969.1, ZP_(—)06659935.1, YP_(—)410143.1, NP_(—)290475.1, ZP_(—)03027945.1, EFZ59092.1, YP_(—)002295406.1, CBG37050.1, EGP22872.1, EGE62411.1, EGC97040.1, ZP_(—)05435276.1, YP_(—)002400349.1, EGB59498.1, EFW54756.1, ZP_(—)08361144.1, YP_(—)001465329.1, YP_(—)002384701.1, YP_(—)002409079.1, ZP_(—)06655947.1, YP_(—)002414995.1, EGB69559.1, YP_(—)859446.1, EGC05061.1, ZP_(—)02904263.1, ZP_(—)08386168.1, YP_(—)543378.1, ZP_(—)08366394.1, ZP_(—)03066325.1, YP_(—)001746177.1, ZP_(—)07154548.1, ZP_(—)03070708.1, NP_(—)756651.1, YP_(—)312775.1, YP_(—)671919.1, YP_(—)002331615.1, YP_(—)003367348.1, ZP_(—)07449249.1, ZP_(—)04558440.1, ZP_(—)06354347.1, YP_(—)001451792.1, YP_(—)004732312.1, ZP_(—)06938722.1, NP_(—)457770.1, ZP_(—)02834646.1, ZP_(—)02658975.1, ZP_(—)03221210.1, EFY10008.1, YP_(—)001591070.1, YP_(—)218866.1, YP_(—)003943710.1, ZP_(—)03086141.1, ZP_(—)03163187.1, ZP_(—)08495783.1, EGE35936.1, YP_(—)003615423.1, YP_(—)002228261.1, YP_(—)002148907.1, ZP_(—)05970963.1, YP_(—)002241092.1, YP_(—)004591812.1, YP_(—)001178656.1, ZP_(—)08302761.1, YP_(—)002917175.1, YP_(—)001337974.1, Q9F0Y6.1, ZP_(—)06014072.1, YP_(—)001439748.1, YP_(—)003208639.1, 3GOA_A, YP_(—)003739634.1, ZP_(—)06192593.1, YP_(—)001906199.1, YP_(—)001476498.1, YP_(—)003019596.1, YP_(—)003261566.1, ZP_(—)03831341.1, ZP_(—)07380062.1, YP_(—)048334.1, YP_(—)003933022.1, ZP_(—)07953301.1, YP_(—)004114075.1, YP_(—)002647269.1, ADP11111.1, ZP_(—)03827988.1, ZP_(—)06638308.1, YP_(—)004214865.1, YP_(—)003518495.1, ZP_(—)04616541.1, BAK13440.1, CBX79036.1, YP_(—)003529580.1, ZP_(—)04628384.1, ZP_(—)04634365.1, ZP_(—)04641537.1, ZP_(—)04612254.1, ZP_(—)04637126.1, YP_(—)003331801.1, YP_(—)001004652.1, YP_(—)004296469.1, YP_(—)003006181.1, ZP_(—)04620755.1, 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YP_(—)004125334.1, ZP_(—)07952596.1, YP_(—)001479268.1, ZP_(—)07043083.1, YP_(—)003644271.1, NP_(—)421210.1, ZP_(—)02882590.1, EGP25245.1, YP_(—)233920.1, EGD00226.1, YP_(—)004418315.1, ADY81914.1, ZP_(—)04944762.1, YP_(—)003603999.1, YP_(—)001060552.1, ZP_(—)03026966.1, YP_(—)441123.1, YP_(—)201177.1, ZP_(—)05117283.1, YP_(—)004232360.1, YP_(—)002802211.1, YP_(—)106085.1, YP_(—)258448.1, YP_(—)001989549.1, NP_(—)945866.1, ZP_(—)03573123.1, YP_(—)283604.1, YP_(—)004702122.1, ZP_(—)03398400.1, YP_(—)105310.1, YP_(—)001479310.1, CAC41637.1, ZP_(—)02372747.1, YP_(—)001578772.1, ZP_(—)08181762.1, ZP_(—)00439074.2, ADX92638.1, ZP_(—)03790444.1, YP_(—)110295.1, YP_(—)002439726.1, YP_(—)004361986.1, ZP_(—)04946665.1, YP_(—)003751825.1, YP_(—)001061488.1, ZP_(—)03545148.1, ZP_(—)01767462.1, ZP_(—)01769818.1, YP_(—)990241.1, YP_(—)002382777.1, YP_(—)002898389.1, YP_(—)003452421.1, EGH66881.1, CBW26817.1, YP_(—)004352451.1, EGC07165.1, YP_(—)003982691.1, ZP_(—)02906520.1, YP_(—)410799.1, YP_(—)001189077.1, YP_(—)004226900.1, ADP96997.1, YP_(—)237079.1, YP_(—)002946310.1, YP_(—)004029037.1, NP_(—)745423.1, ZP_(—)08139209.1, YP_(—)004294989.1, NP_(—)251630.1, EGH73592.1, ZP_(—)04934925.1, ZP_(—)03583227.1, ZP_(—)03584241.1, YP_(—)004684330.1, YP_(—)004501533.1, YP_(—)001186637.1, YP_(—)003980170.1, AEJ98540.1, YP_(—)004688333.1, YP_(—)003276725.1, EGH11975.1, YP_(—)276147.1, YP_(—)790233.1, ZP_(—)01736635.1, YP_(—)002440908.1, YP_(—)002230040.1, YP_(—)724980.1, YP_(—)004231717.1, ZP_(—)01226775.1, ZP_(—)03454556.1, ZP_(—)05586076.1, ZP_(—)02890239.1, YP_(—)001172996.1, ZP_(—)02377875.1, ZP_(—)07202399.1, YP_(—)774661.1, YP_(—)440314.2, YP_(—)443408.1, ZP_(—)06878044.1, ZP_(—)08274339.1, YP_(—)001618203.1, ZP_(—)08631485.1, ZP_(—)01545529.1, ZP_(—)03267843.1, ZP_(—)07797009.1, YP_(—)003376084.1, EGH21143.1, YP_(—)003753513.1, YP_(—)004282234.1, YP_(—)726356.1, ZP_(—)06014951.1, YP_(—)109637.1, ZP_(—)06461447.1, YP_(—)001795795.1, YP_(—)621981.1, ZP_(—)07794257.1, ZP_(—)05060451.1, YP_(—)002919830.1, YP_(—)001796645.1, NP_(—)794063.1, ZP_(—)01365347.1, YP_(—)003610065.1, YP_(—)001462757.1, YP_(—)001807185.1, ZP_(—)04928407.1, YP_(—)002229986.1, ZP_(—)02883901.1, YP_(—)370284.1, ZP_(—)05053491.1, AAC24332.1, ZP_(—)04929241.1, ZP_(—)00943679.1, YP_(—)001766064.1, YP_(—)001670661.1, YP_(—)003296167.1, YP_(—)003773673.1, NP_(—)250691.1, ZP_(—)05823066.1, YP_(—)004381309.1, YP_(—)004714773.1, YP_(—)746962.1, YP_(—)002513585.1, YP_(—)294674.1, YP_(—)004593822.1, YP_(—)622032.1, YP_(—)001897940.1, YP_(—)001335713.1, YP_(—)001856626.1, YP_(—)791238.1, YP_(—)004140309.1, YP_(—)001269802.1, ZP_(—)06879064.1, ZP_(—)01736318.1, ZP_(—)02886139.1, ZP_(—)04941413.1, YP_(—)001670851.1, YP_(—)371023.1, YP_(—)002980343.1, YP_(—)002795605.1, ZP_(—)06069679.1, ZP_(—)02463309.1, ZP_(—)05785212.1, YP_(—)001793049.1, YP_(—)003965283.1, YP_(—)001233153.1, YP_(—)299776.1, ZP_(—)06498740.1, AEJ99148.1, YP_(—)004685690.1, YP_(—)003746771.1, YP_(—)004381943.1, YP_(—)004378973.1, YP_(—)004314684.1, EGH79619.1, ZP_(—)04882546.1, YP_(—)347001.1, YP_(—)347471.1, YP_(—)001757758.1, YP_(—)002911324.1, NP_(—)518596.1, ZP_(—)00948908.1, YP_(—)442777.1, YP_(—)002874183.1, YP_(—)002230989.1, YP_(—)004360850.1, ABC36127.1, YP_(—)004696127.1, YP_(—)002799527.1, YP_(—)001631275.1, YP_(—)626125.1, ZP_(—)05090649.1, ZP_(—)07774002.1, ZP_(—)04940525.1, AEK60371.1, ADR60119.1, YP_(—)102981.1, YP_(—)003451423.1, NP_(—)743536.1, CAA45255.1, in particular YP_(—)790159.1, ZP_(—)06877967.1, NP_(—)251703.1, EGH66370.1, EGH10832.1, YP_(—)349606.1, YP_(—)236359.1, ZP_(—)07263340.1, EGH95844.1, NP_(—)793296.1, 1WDK_C, P28790.2, YP_(—)259060.1, ZP_(—)04587908.1, EGH45981.1, ZP_(—)07774144.1, EGH84449.1, YP_(—)275369.1, ZP_(—)07005686.1, YP_(—)001172247.1, YP_(—)004352962.1, ACP17922.1, YP_(—)002871196.1, ZP_(—)08142929.1, YP_(—)004701153.1, YP_(—)001667916.1, YP_(—)001268913.1, Q93Q11.1, Q9R9W0.1, NP_(—)744286.1, YP_(—)001187077.1, YP_(—)609234.1, YP_(—)004379417.1, YP_(—)004474975.1, ABP88737.1, EGH76239.1, EGH29725.1, ZP_(—)06499584.1, YP_(—)001749490.1, ABF82237.1, YP_(—)004713534.1, CAD76924.1, YP_(—)608369.1, AEA83130.1, YP_(—)001171793.1, YP_(—)788379.1, CAE45106.1, NP_(—)248919.1, YP_(—)001348923.1, ZP_(—)07797976.1, YP_(—)001747677.1, NP_(—)250427.1, AAR83740.1, YP_(—)001668851.1, ZP_(—)06495825.1, YP_(—)004379898.1, EGH60624.1, ZP_(—)04933402.1, YP_(—)001345710.1, Q8VPF1.1, YP_(—)004473788.1, EGH77345.1, EGH44350.1, YP_(—)001188713.1, YP_(—)004380648.1, YP_(—)001188079.1, ZP_(—)08142248.1, YP_(—)004703691.1, ZP_(—)04936650.1, YP_(—)606872.1, YP_(—)610092.1, ADR61907.1, ZP_(—)04934614.1, ZP_(—)07262554.1, YP_(—)001747891.1, Q51956.1, YP_(—)002871766.1, NP_(—)746745.1, YP_(—)001267798.1, YP_(—)004703877.1, EGH73771.1, EGH61062.1, YP_(—)233920.1, YP_(—)258448.1, YP_(—)004702122.1, ZP_(—)03398400.1, YP_(—)002439726.1, EGH66881.1, YP_(—)004352451.1, YP_(—)001189077.1, YP_(—)237079.1, NP_(—)745423.1, ZP_(—)08139209.1, NP_(—)251630.1, EGH73592.1, ZP_(—)04934925.1, YP_(—)001186637.1, EGH11975.1, YP_(—)276147.1, YP_(—)790233.1, YP_(—)002440908.1, YP_(—)001172996.1, ZP_(—)06878044.1, ZP_(—)07797009.1, EGH21143.1, ZP_(—)06461447.1, ZP_(—)07794257.1, NP_(—)794063.1, ZP_(—)01365347.1, ZP_(—)04928407.1, AAC24332.1, ZP_(—)04929241.1, YP_(—)001670661.1, NP_(—)250691.1, YP_(—)004381309.1, YP_(—)004714773.1, YP_(—)791238.1, YP_(—)001269802.1, ZP_(—)06879064.1, YP_(—)001670851.1, ZP_(—)06498740.1, YP_(—)004381943.1, YP_(—)004378973.1, EGH79619.1, YP_(—)347001.1, YP_(—)347471.1, YP_(—)002874183.1, ZP_(—)07774002.1, ADR60119.1, NP_(—)743536.1, YP_(—)001269653.1, ZP_(—)06482365.1, ADI95330.1, ZP_(—)07003619.1, BAB96553.1, ZP_(—)07777009.1, ABA10831.1, YP_(—)273131.1, YP_(—)259428.1, EFW86233.1, EGH85840.1, ZP_(—)07774597.1, EGH54613.1, YP_(—)004353129.1, YP_(—)002871014.1, YP_(—)001171232.1, EGH67454.1, EFW82139.1, ZP_(—)04590526.1, EGH58132.1, EGH06629.1, EGH99157.1, ZP_(—)05638078.1, NP_(—)790796.1, AEE59172.1, YP_(—)026272.1, YP_(—)002389323.1, EGB30581.1, YP_(—)001460637.1, YP_(—)001727089.1, CAB40810.1, ZP_(—)03049054.1, ZP_(—)08356522.1, ZP_(—)06664573.1, AAA67642.1, YP_(—)003236969.1, ZP_(—)06659935.1, NP_(—)290475.1, ZP_(—)03027945.1, EFZ59092.1, YP_(—)002295406.1, CBG37050.1, EGP22872.1, EGE62411.1, YP_(—)002400349.1, EGB59498.1, ZP_(—)08361144.1, YP_(—)001465329.1, YP_(—)002409079.1, ZP_(—)06655947.1, YP_(—)002414995.1, EGB69559.1, YP_(—)859446.1, ZP_(—)08386168.1, YP_(—)543378.1, ZP_(—)08366394.1, YP_(—)001746177.1, ZP_(—)07154548.1, ZP_(—)03070708.1, NP_(—)756651.1, YP_(—)671919.1, YP_(—)002331615.1, ZP_(—)07449249.1, ZP_(—)06938722.1, ZP_(—)03086141.1, ZP_(—)07189177.1, ZP_(—)07136312.1, EFZ47010.1, ZP_(—)07136311.1, EFZ47009.1, ZP_(—)03026937.1, EGB73439.1, EGP25245.1, ZP_(—)03026966.1, YP_(—)001462757.1, CAP76727.1, YP_(—)670163.1, and particularly preferably YP_(—)026272.1, AAA67642.1, ZP_(—)07593202.1, YP_(—)004701153.1, YP_(—)001667916.1, YP_(—)001268913.1, Q9R9W0.1, NP_(—)744286.1, ABP88737.1, YP_(—)001749490.1, YP_(—)001747677.1, YP_(—)001668851.1, YP_(—)004703691.1, ADR61907.1, YP_(—)001747891.1, Q51956.1, NP_(—)746745.1, YP_(—)001267798.1, YP_(—)004703877.1, YP_(—)004702122.1, NP_(—)745423.1, AAC24332.1, YP_(—)001670661.1, YP_(—)001269802.1, YP_(—)001670851.1, ADR60119.1, NP_(—)743536.1, YP_(—)001269653.1, ADI95330.1, BAB96553.1, YP_(—)001172247.1, YP_(—)004713534.1, AEA83130.1, YP_(—)001171793.1, YP_(—)001172996.1, YP_(—)004714773.1, YP_(—)001171232.1, YP_(—)349606.1, YP_(—)259060.1, ZP_(—)07774144.1, YP_(—)002871196.1, ABF82237.1, YP_(—)002871766.1, YP_(—)258448.1, YP_(—)347001.1, YP_(—)347471.1, YP_(—)002874183.1, ZP_(—)07774002.1, ZP_(—)07777009.1, YP_(—)259428.1, ZP_(—)07774597.1, YP_(—)002871014.1, and proteins with a polypeptide sequence wherein up to 60%, preferably up to 25%, particularly preferably up to 15%, in particular up to 10, 9, 8, 7, 6, 5, 4, 3, 2 or 1% of the amino acid residues compared to the aforementioned reference sequences are modified by deletion, insertion, substitution or a combination thereof and which still possess at least 50%, preferably 65%, particularly preferably 80%, in particular more than 90% of the activity of the protein with the corresponding, aforementioned reference sequence, wherein 100% activity of the reference protein is understood to mean the increasing of the activity of the cells used as a biocatalyst, i.e. the quantity of substance converted per unit time based on the cell quantity used (units per gram cell dry weight [U/g CDW]) in comparison to the activity of the biocatalyst in the absence of the reference protein, wherein the activity in this connection and in connection with the determination of the activity of the enzyme E_(f) in general is understood to mean in particular the conversion of 3-oxo-dodecanoyl-CoA thioesters and CoA to decanoyl-CoA thioesters and acetyl-CoA.

Sixth Genetic Modification for Intensification of the Acyl-ACP Thioester Synthesis

According to the invention, the microorganisms have a sixth genetic modification, so that compared to their wild type they are capable of forming more acyl-ACP thioester from at least one simple carbon source. An overview of correspondingly desirable genetic modifications is to be found in FIG. 1 of WO2008119082, paragraph 1 (Fatty Acid Production Increase/Product Production Increase).

This has the technical effect that formation of carboxylic acids and carboxylate ester intensified by the first genetic modification, but also of ω-functionalized carboxylic acids and carboxylate esters formed in greater quantity through the second, third, fourth, fifth or seventh genetic modification, is still further intensified.

Thus configured organisms preferred according to the invention are also outstandingly suitable for the production of compounds which are selected from

α,ω-alkanediols, α,ω-alkanedialdehydes, α-oxo-ω-hydroxyalkanes and α,ω-alkanediamines, since compounds of these classes are produced in significant quantities together with ω-functionalized alkanoic acids and ω-functionalized alkanoate esters Seventh Genetic Modification for the Production of ω-Functionalized Carboxylic Acids and Co-Functionalized Carboxylate Esters with a Terminal Double Bond

The microorganisms according to the invention can additionally be configured such that they are advantageously suitable for the production of ω-functionalized carboxylic acids and ω-functionalized carboxylate esters with a terminal double bond. For this, preferred microorganisms contain a seventh genetic modification which comprises, compared to the enzymatic activity of the wild type of the microorganism, increased activity of an enzyme E_(xi) which catalyses the conversion of ω-carboxycarboxylic acids or ω-carboxycarboxylate esters to carboxylic acids or carboxylate esters with a terminal double bond, selected from the group E_(xi)) Cytochrome P450 fatty acid decarboxylase, which catalyses the conversion of an alkanoic acid with n carbon atoms to a corresponding terminal olefin with n−1 carbon atoms, in particular of dodecanoic acid to undec-10-enoic acid.

Microorganisms preferred according to the invention are those which are obtained when the microorganisms listed below having a seventh genetic modification in the sense of the invention are used as the starting point, in that they are provided with a first and second genetic modification and optionally at least one further genetic modification in the sense of the invention.

WO2009085278 A1 describes, particularly in paragraphs [0033] to [0048], [0056] to [0063] and [0188] to [0202], FIG. 10, table 8, practical examples 5 to 18 and claims 28 to 51 and 188 to 195, microorganisms preferred according to the invention which have a seventh genetic modification, so that compared to their wild type they are capable of forming more fatty acids and fatty acid derivatives, in particular olefins, from at least one simple carbon source. The document also describes E_(xi) preferred according to the invention enzymes and the sequences thereof, particularly in paragraphs [0021] to [0032], [0051] to [0055], [0081] to [0084] and [0160] to [0183], table 8, practical examples 5 to 18, claims 1 to 25 and FIGS. 3, 7 and 9.

Specific Embodiments of Preferable Microorganisms and Enzymes

According to the invention, microorganisms are particularly preferably selected from those which have

a first and a second genetic modification in the sense of the invention, a first, a second and a fifth genetic modification in the sense of the invention, a first, a second and a third genetic modification in the sense of the invention, a first, a second, a third and a fifth genetic modification in the sense of the invention, a first, a second and a fourth genetic modification in the sense of the invention, a first, a second, a fourth and a fifth genetic modification in the sense of the invention, a first, a second, a third and a fourth genetic modification in the sense of the invention, a first, a second, a third, a fourth and a fifth genetic modification in the sense of the invention, a first, a second and a seventh genetic modification in the sense of the invention, a first, a second, a fifth and a seventh genetic modification in the sense of the invention, a first, a second, a third and a seventh genetic modification in the sense of the invention or a first, a second, a third, a fifth and a seventh genetic modification in the sense of the invention a first, a second and a sixth genetic modification in the sense of the invention, a first, a second, a fifth and a sixth genetic modification in the sense of the invention, a first, a second, a third and a sixth genetic modification in the sense of the invention, a first, a second, a third, a fifth and a sixth genetic modification in the sense of the invention, a first, a second, a fourth and a sixth genetic modification in the sense of the invention, a first, a second, a fourth, a fifth and a sixth genetic modification in the sense of the invention, a first, a second, a third, a fourth and a sixth genetic modification in the sense of the invention, a first, a second, a third, a fourth, a fifth and a sixth genetic modification in the sense of the invention, a first, a second, a sixth and a seventh genetic modification in the sense of the invention, a first, a second, a fifth, a sixth and a seventh genetic modification in the sense of the invention, a first, a second, a third, a sixth and a seventh genetic modification in the sense of the invention or a first, a second, a third, a fifth, sixth and a seventh genetic modification in the sense of the invention.

According to the invention, microorganisms are particularly preferable which have a first genetic modification, so that compared to their wild type they are capable of forming more carboxylic acids and carboxylate ester from at least one simple carbon source, wherein the first genetic modification displays, compared to the enzymatic activity of the wild type of the microorganism, increased activity of at least one of the enzymes E_(i) or of one of the enzymes with a polypeptide sequence wherein up to 60%, preferably up to 25%, particularly preferably up to 15%, in particular up to 10, 9, 8, 7, 6, 5, 4, 3, 2 or 1% amino acid residues compared to the sequences stated in the following table by reference are modified by deletion, insertion, substitution or a combination thereof and which still possess at least 50%, preferably 65%, particularly preferably 80%, in particular more than 90% of the activity of the protein with the respective reference sequence, wherein 100% activity of the reference protein is understood to mean the increasing of the activity of the cells used as a biocatalyst, i.e. the quantity of substance converted per unit time based on the cell quantity used (units per gram cell dry weight [U/g CDW]) in comparison to the activity of the biocatalyst in the absence of the reference protein, wherein the activity in this connection in general is understood to mean in particular the hydrolysis of an ACP thioester with the carbon chain length assigned in the following table to the individual enzymes E_(i), and the carboxylic acid and carboxylate ester have a carbon chain length of the carboxylic acid part, as shown in the following table:

Enzyme E_(i) selected from Carbon chain length AAC49269.1, CAB60830.1, AAC49179.1, C8 AAC49784.1, ABB71579.1, CAC19934.1 and SEQ ID Nos. 26, 29, 33, 38, 40, 97 and 99 of WO2011008565 AAC49269.1, CAB60830.1, AAC49179.1, C10 AAC49784.1, ABB71579.1, CAC19934.1 and SEQ ID Nos. 73, 75, 87 and 89 of WO2011008565. Q41635.1, Q39473.1, AAC49180.1, C12 CAC19934.1, AAC72881.1, AAC49783.1, AAC49784.1 and SEQ ID Nos. 49 and 51 of WO2011008565. Q41635.1, Q39473.1, AAC49180.1, C14 CAC19934.1, AAC72881.1 AAC49783.1, AAC49784.1 and SEQ ID Nos. 49, 51, 53, 55, 61, 63, 67, 69, 77, 79, 83 and 85 of WO2011008565.

The aforementioned deletions of amino acid residues compared to the sequences stated in the above table by reference relate in particular to deletions at the N- and/or C-terminus, in particular at the N-Terminus. Particularly preferably, the aforementioned N-terminus is that of a plant plastid targeting sequence. Such plant plastid targeting sequences can for example be predicted by means of the algorithms utilized by the predictive tool TargetP 1.1 (www.cbs.dtu.dk/servicesiTargetP/) and described in the following publications, preferably without use of cutoffs:

Predicting Subcellular Localization of Proteins Based on their N-Terminal Amino Acid Sequence.

Olof Emanuelsson, Henrik Nielsen, Soren Brunak and Gunnar von Heijne.

J. Mol. Biol., 300: 1005-1016, 2000 and Identification of prokaryotic and eukaryotic signal peptides and prediction of their cleavage sites. Henrik Nielsen, Jacob Engelbrecht, Soren Brunak and Gunnar von Heijne. Protein Engineering, 10:1-6, 1997.

Microorganisms quite especially preferred according to the invention (abbreviated as MO) are outstandingly suitable for the production of ω-aminocarboxylic acids and have increased or decreased enzyme activities (abbreviated as E) described in the following table, where these can in addition advantageously be combined with an increased enzyme activity compared to the wild type of the microorganism, which is described for the 3-ketoacyl-ACP (Acyl Carrrier Protein) synthase III (EC 2.3.1.41), in particular that from plants, preferably that from plants the seeds whereof contain fatty acids with alkyl residues shorter than 14 C atoms, and particularly preferably that from plants of the genera Cuphea, Elaeis, Cocos, Umbellularia and Cinnamomum and gene products selected from AccA, AccB, AccC, AccD, AceE, AceF, Lpd, AcpP, FabA, FabB, FabD, FabF, FabG, FabH, Fabl, FabZ, PanD, PanK, UdhA, PntA or PntB. Any combinations of at least two of these enzyme activities can advantageously be increased.

In addition, moreover, it can be advantageous if the microorganism is provided with a lower enzyme activity compared to the wild type of the microorganism, which is described for the gene products selected from TdcE, PflA, PflB, PflC, PflD, PoxB, YgfG, AckA, AckB, TdcD, Pta, LdhA, AdhE, MgsA, FdnG, FdnH, FdnI, FdhF, FdoG, FdoH, FdoI, PrpC, PrpD, PrpF, PrpB, TdcD, Pdc, PorA, PorB, PorC, PorD, AlsS, IlvB, IlvM, IlvN, IlvG, IlyI, IlvH, AlsD, ButB, Thl, ThlA, ThlB, PhaA, PhaB, Crt, BdhA, BdhB, Adc, Adh, CtfB, AtoA, AtoD, LdhL, GltA, FabR, FhuA, Dld, LldA or LldP, singly or in any combination.

MO E increased E decreased 1 E_(1a)E₂ 2 E_(1b)E₂ 3 E_(1a)E₂E₃ 4 E_(1b)E₂E₃ 5 E_(1a)E₂E_(i) 6 E_(1b)E₂E_(i) 7 E_(1a)E₂E_(ii) 8 E_(1b)E₂E_(ii) 9 E_(1a)E₂E_(ii)E_(iib) 10 E_(1b)E₂E_(ii)E_(iib) 11 E_(1a)E₂E₃E_(i) 12 E_(1b)E₂E₃E_(i) 13 E_(1a)E₂E₃E_(ii) 14 E_(1b)E₂E₃E_(ii) 15 E_(1a)E₂E₃E_(ii)E_(iib) 16 E_(1b)E₂E₃E_(ii)E_(iib) 17 E_(1a)E₂E₄ 18 E_(1b)E₂E₄ 19 E_(1a)E₂E₃E₄ 20 E_(1b)E₂E₃E₄ 21 E_(1a)E₂E_(i)E₄ 22 E_(1b)E₂E_(i)E₄ 23 E_(1a)E₂E_(ii)E₄ 24 E_(1b)E₂E_(ii)E₄ 25 E_(1a)E₂E_(ii)E_(iib)E₄ 26 E_(1b)E₂E_(ii)E_(iib)E₄ 27 E_(1a)E₂E₃E_(i)E₄ 28 E_(1b)E₂E₃E_(i)E₄ 29 E_(1a)E₂E₃E_(ii)E₄ 30 E_(1b)E₂E₃E_(ii)E₄ 31 E_(1a)E₂E₃E_(ii)E_(iib)E₄ 32 E_(1b)E₂E₃E_(ii)E_(iib)E₄ 33 E_(1a)E₂E_(iii) 34 E_(1b)E₂E_(iii) 35 E_(1a)E₂E₃E_(iii) 36 E_(1b)E₂E₃E_(iii) 37 E_(1a)E₂E_(iii)E₄ 38 E_(1b)E₂E_(iii)E₄ 39 E_(1a)E₂E₃E_(iii)E₄ 40 E_(1b)E₂E₃E_(iii)E₄ 41 E_(1a)E₂E_(iv) 42 E_(1b)E₂E_(iv) 43 E_(1a)E₂E₃E_(iv) 44 E_(1b)E₂E₃E_(iv) 45 E_(1a)E₂E_(iv)E₄ 46 E_(1b)E₂E_(iv)E₄ 47 E_(1a)E₂E₃E_(iv)E₄ 48 E_(1b)E₂E₃E_(iv)E₄ 49 E_(1a)E₂ E₄* 50 E_(1b)E₂ E₄* 51 E_(1a)E₂E₃ E₄* 52 E_(1b)E₂E₃ E₄* 53 E_(1a)E₂E_(i) E₄* 54 E_(1b)E₂E_(i) E₄* 55 E_(1a)E₂E_(ii) E₄* 56 E_(1b)E₂E_(ii) E₄* 57 E_(1a)E₂E_(ii)E_(iib) E₄* 58 E_(1b)E₂E_(ii)E_(iib) E₄* 59 E_(1a)E₂E₃E_(i) E₄* 60 E_(1b)E₂E₃E_(i) E₄* 61 E_(1a)E₂E₃E_(ii) E₄* 62 E_(1b)E₂E₃E_(ii) E₄* 63 E_(1a)E₂E₃E_(ii)E_(iib) E₄* 64 E_(1b)E₂E₃E_(ii)E_(iib) E₄* 65 E_(1a)E₂E₄ E₄* 66 E_(1b)E₂E₄ E₄* 67 E_(1a)E₂E₃E₄ E₄* 68 E_(1b)E₂E₃E₄ E₄* 69 E_(1a)E₂E_(i)E₄ E₄* 70 E_(1b)E₂E_(i)E₄ E₄* 71 E_(1a)E₂E_(ii)E₄ E₄* 72 E_(1b)E₂E_(ii)E₄ E₄* 73 E_(1a)E₂E_(ii)E_(iib)E₄ E₄* 74 E_(1b)E₂E_(ii)E_(iib)E₄ E₄* 75 E_(1a)E₂E₃E_(i)E₄ E₄* 76 E_(1b)E₂E₃E_(i)E₄ E₄* 77 E_(1a)E₂E₃E_(ii)E₄ E₄* 78 E_(1b)E₂E₃E_(ii)E₄ E₄* 79 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E₄* 80 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E₄* 81 E_(1a)E₂E_(iii) E₄* 82 E_(1b)E₂E_(iii) E₄* 83 E_(1a)E₂E₃E_(iii) E₄* 84 E_(1b)E₂E₃E_(iii) E₄* 85 E_(1a)E₂E_(iii)E₄ E₄* 86 E_(1b)E₂E_(iii)E₄ E₄* 87 E_(1a)E₂E₃E_(iii)E₄ E₄* 88 E_(1b)E₂E₃E_(iii)E₄ E₄* 89 E_(1a)E₂E_(iv) E₄* 90 E_(1b)E₂E_(iv) E₄* 91 E_(1a)E₂E₃E_(iv) E₄* 92 E_(1b)E₂E₃E_(iv) E₄* 93 E_(1a)E₂E_(iv)E₄ E₄* 94 E_(1b)E₂E_(iv)E₄ E₄* 95 E_(1a)E₂E₃E_(iv)E₄ E₄* 96 E_(1b)E₂E₃E_(iv)E₄ E₄* 97 E_(1a)E₂ E₅ 98 E_(1b)E₂ E₅ 99 E_(1a)E₂E₃ E₅ 100 E_(1b)E₂E₃ E₅ 101 E_(1a)E₂E_(i) E₅ 102 E_(1b)E₂E_(i) E₅ 103 E_(1a)E₂E_(ii) E₅ 104 E_(1b)E₂E_(ii) E₅ 105 E_(1a)E₂E_(ii)E_(iib) E₅ 106 E_(1b)E₂E_(ii)E_(iib) E₅ 107 E_(1a)E₂E₃E_(i) E₅ 108 E_(1b)E₂E₃E_(i) E₅ 109 E_(1a)E₂E₃E_(ii) E₅ 110 E_(1b)E₂E₃E_(ii) E₅ 111 E_(1a)E₂E₃E_(ii)E_(iib) E₅ 112 E_(1b)E₂E₃E_(ii)E_(iib) E₅ 113 E_(1a)E₂E₄ E₅ 114 E_(1b)E₂E₄ E₅ 115 E_(1a)E₂E₃E₄ E₅ 116 E_(1b)E₂E₃E₄ E₅ 117 E_(1a)E₂E_(i)E₄ E₅ 118 E_(1b)E₂E_(i)E₄ E₅ 119 E_(1a)E₂E_(ii)E₄ E₅ 120 E_(1b)E₂E_(ii)E₄ E₅ 121 E_(1a)E₂E_(ii)E_(iib)E₄ E₅ 122 E_(1b)E₂E_(ii)E_(iib)E₄ E₅ 123 E_(1a)E₂E₃E_(i)E₄ E₅ 124 E_(1b)E₂E₃E_(i)E₄ E₅ 125 E_(1a)E₂E₃E_(ii)E₄ E₅ 126 E_(1b)E₂E₃E_(ii)E₄ E₅ 127 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E₅ 128 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E₅ 129 E_(1a)E₂E_(iii) E₅ 130 E_(1b)E₂E_(iii) E₅ 131 E_(1a)E₂E₃E_(iii) E₅ 132 E_(1b)E₂E₃E_(iii) E₅ 133 E_(1a)E₂E_(iii)E₄ E₅ 134 E_(1b)E₂E_(iii)E₄ E₅ 135 E_(1a)E₂E₃E_(iii)E₄ E₅ 136 E_(1b)E₂E₃E_(iii)E₄ E₅ 137 E_(1a)E₂E_(iv) E₅ 138 E_(1b)E₂E_(iv) E₅ 139 E_(1a)E₂E₃E_(iv) E₅ 140 E_(1b)E₂E₃E_(iv) E₅ 141 E_(1a)E₂E_(iv)E₄ E₅ 142 E_(1b)E₂E_(iv)E₄ E₅ 143 E_(1a)E₂E₃E_(iv)E₄ E₅ 144 E_(1b)E₂E₃E_(iv)E₄ E₅ 145 E_(1a)E₂ E₄*E₅ 146 E_(1b)E₂ E₄*E₅ 147 E_(1a)E₂E₃ E₄*E₅ 148 E_(1b)E₂E₃ E₄*E₅ 149 E_(1a)E₂E_(i) E₄*E₅ 150 E_(1b)E₂E_(i) E₄*E₅ 151 E_(1a)E₂E_(ii) E₄*E₅ 152 E_(1b)E₂E_(ii) E₄*E₅ 153 E_(1a)E₂E_(ii)E_(iib) E₄*E₅ 154 E_(1b)E₂E_(ii)E_(iib) E₄*E₅ 155 E_(1a)E₂E₃E_(i) E₄*E₅ 156 E_(1b)E₂E₃E_(i) E₄*E₅ 157 E_(1a)E₂E₃E_(ii) E₄*E₅ 158 E_(1b)E₂E₃E_(ii) E₄*E₅ 159 E_(1a)E₂E₃E_(ii)E_(iib) E₄*E₅ 160 E_(1b)E₂E₃E_(ii)E_(iib) E₄*E₅ 161 E_(1a)E₂E₄ E₄*E₅ 162 E_(1b)E₂E₄ E₄*E₅ 163 E_(1a)E₂E₃E₄ E₄*E₅ 164 E_(1b)E₂E₃E₄ E₄*E₅ 165 E_(1a)E₂E_(i)E₄ E₄*E₅ 166 E_(1b)E₂E_(i)E₄ E₄*E₅ 167 E_(1a)E₂E_(ii)E₄ E₄*E₅ 168 E_(1b)E₂E_(ii)E₄ E₄*E₅ 169 E_(1a)E₂E_(ii)E_(iib)E₄ E₄*E₅ 170 E_(1b)E₂E_(ii)E_(iib)E₄ E₄*E₅ 171 E_(1a)E₂E₃E_(i)E₄ E₄*E₅ 172 E_(1b)E₂E₃E_(i)E₄ E₄*E₅ 173 E_(1a)E₂E₃E_(ii)E₄ E₄*E₅ 174 E_(1b)E₂E₃E_(ii)E₄ E₄*E₅ 175 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E₄*E₅ 176 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E₄*E₅ 177 E_(1a)E₂E_(iii) E₄*E₅ 178 E_(1b)E₂E_(iii) E₄*E₅ 179 E_(1a)E₂E₃E_(iii) E₄*E₅ 180 E_(1b)E₂E₃E_(iii) E₄*E₅ 181 E_(1a)E₂E_(iii)E₄ E₄*E₅ 182 E_(1b)E₂E_(iii)E₄ E₄*E₅ 183 E_(1a)E₂E₃E_(iii)E₄ E₄*E₅ 184 E_(1b)E₂E₃E_(iii)E₄ E₄*E₅ 185 E_(1a)E₂E_(iv) E₄*E₅ 186 E_(1b)E₂E_(iv) E₄*E₅ 187 E_(1a)E₂E₃E_(iv) E₄*E₅ 188 E_(1b)E₂E₃E_(iv) E₄*E₅ 189 E_(1a)E₂E_(iv)E₄ E₄*E₅ 190 E_(1b)E₂E_(iv)E₄ E₄*E₅ 191 E_(1a)E₂E₃E_(iv)E₄ E₄*E₅ 192 E_(1b)E₂E₃E_(iv)E₄ E₄*E₅ 193 E_(1a)E₂ AlkL 194 E_(1b)E₂ AlkL 195 E_(1a)E₂E₃ AlkL 196 E_(1b)E₂E₃ AlkL 197 E_(1a)E₂E_(i) AlkL 198 E_(1b)E₂E_(i) AlkL 199 E_(1a)E₂E_(ii) AlkL 200 E_(1b)E₂E_(ii) AlkL 201 E_(1a)E₂E_(ii)E_(iib) AlkL 202 E_(1b)E₂E_(ii)E_(iib) AlkL 203 E_(1a)E₂E₃E_(i) AlkL 204 E_(1b)E₂E₃E_(i) AlkL 205 E_(1a)E₂E₃E_(ii) AlkL 206 E_(1b)E₂E₃E_(ii) AlkL 207 E_(1a)E₂E₃E_(ii)E_(iib) AlkL 208 E_(1b)E₂E₃E_(ii)E_(iib) AlkL 209 E_(1a)E₂E₄ AlkL 210 E_(1b)E₂E₄ AlkL 211 E_(1a)E₂E₃E₄ AlkL 212 E_(1b)E₂E₃E₄ AlkL 213 E_(1a)E₂E_(i)E₄ AlkL 214 E_(1b)E₂E_(i)E₄ AlkL 215 E_(1a)E₂E_(ii)E₄ AlkL 216 E_(1b)E₂E_(ii)E₄ AlkL 217 E_(1a)E₂E_(ii)E_(iib)E₄ AlkL 218 E_(1b)E₂E_(ii)E_(iib)E₄ AlkL 219 E_(1a)E₂E₃E_(i)E₄ AlkL 220 E_(1b)E₂E₃E_(i)E₄ AlkL 221 E_(1a)E₂E₃E_(ii)E₄ AlkL 222 E_(1b)E₂E₃E_(ii)E₄ AlkL 223 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkL 224 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkL 225 E_(1a)E₂E_(iii) AlkL 226 E_(1b)E₂E_(iii) AlkL 227 E_(1a)E₂E₃E_(iii) AlkL 228 E_(1b)E₂E₃E_(iii) AlkL 229 E_(1a)E₂E_(iii)E₄ AlkL 230 E_(1b)E₂E_(iii)E₄ AlkL 231 E_(1a)E₂E₃E_(iii)E₄ AlkL 232 E_(1b)E₂E₃E_(iii)E₄ AlkL 233 E_(1a)E₂E_(iv) AlkL 234 E_(1b)E₂E_(iv) AlkL 235 E_(1a)E₂E₃E_(iv) AlkL 236 E_(1b)E₂E₃E_(iv) AlkL 237 E_(1a)E₂E_(iv)E₄ AlkL 238 E_(1b)E₂E_(iv)E₄ AlkL 239 E_(1a)E₂E₃E_(iv)E₄ AlkL 240 E_(1b)E₂E₃E_(iv)E₄ AlkL 241 E_(1a)E₂ AlkL E₄* 242 E_(1b)E₂ AlkL E₄* 243 E_(1a)E₂E₃ AlkL E₄* 244 E_(1b)E₂E₃ AlkL E₄* 245 E_(1a)E₂E_(i) AlkL E₄* 246 E_(1b)E₂E_(i) AlkL E₄* 247 E_(1a)E₂E_(ii) AlkL E₄* 248 E_(1b)E₂E_(ii) AlkL E₄* 249 E_(1a)E₂E_(ii)E_(iib) AlkL E₄* 250 E_(1b)E₂E_(ii)E_(iib) AlkL E₄* 251 E_(1a)E₂E₃E_(i) AlkL E₄* 252 E_(1b)E₂E₃E_(i) AlkL E₄* 253 E_(1a)E₂E₃E_(ii) AlkL E₄* 254 E_(1b)E₂E₃E_(ii) AlkL E₄* 255 E_(1a)E₂E₃E_(ii)E_(iib) AlkL E₄* 256 E_(1b)E₂E₃E_(ii)E_(iib) AlkL E₄* 257 E_(1a)E₂E₄ AlkL E₄* 258 E_(1b)E₂E₄ AlkL E₄* 259 E_(1a)E₂E₃E₄ AlkL E₄* 260 E_(1b)E₂E₃E₄ AlkL E₄* 261 E_(1a)E₂E_(i)E₄ AlkL E₄* 262 E_(1b)E₂E_(i)E₄ AlkL E₄* 263 E_(1a)E₂E_(ii)E₄ AlkL E₄* 264 E_(1b)E₂E_(ii)E₄ AlkL E₄* 265 E_(1a)E₂E_(ii)E_(iib)E₄ AlkL E₄* 266 E_(1b)E₂E_(ii)E_(iib)E₄ AlkL E₄* 267 E_(1a)E₂E₃E_(i)E₄ AlkL E₄* 268 E_(1b)E₂E₃E_(i)E₄ AlkL E₄* 269 E_(1a)E₂E₃E_(ii)E₄ AlkL E₄* 270 E_(1b)E₂E₃E_(ii)E₄ AlkL E₄* 271 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkL E₄* 272 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkL E₄* 273 E_(1a)E₂E_(iii) AlkL E₄* 274 E_(1b)E₂E_(iii) AlkL E₄* 275 E_(1a)E₂E₃E_(iii) AlkL E₄* 276 E_(1b)E₂E₃E_(iii) AlkL E₄* 277 E_(1a)E₂E_(iii)E₄ AlkL E₄* 278 E_(1b)E₂E_(iii)E₄ AlkL E₄* 279 E_(1a)E₂E₃E_(iii)E₄ AlkL E₄* 280 E_(1b)E₂E₃E_(iii)E₄ AlkL E₄* 281 E_(1a)E₂E_(iv) AlkL E₄* 282 E_(1b)E₂E_(iv) AlkL E₄* 283 E_(1a)E₂E₃E_(iv) AlkL E₄* 284 E_(1b)E₂E₃E_(iv) AlkL E₄* 285 E_(1a)E₂E_(iv)E₄ AlkL E₄* 286 E_(1b)E₂E_(iv)E₄ AlkL E₄* 287 E_(1a)E₂E₃E_(iv)E₄ AlkL E₄* 288 E_(1b)E₂E₃E_(iv)E₄ AlkL E₄* 289 E_(1a)E₂ AlkL E₅ 290 E_(1b)E₂ AlkL E₅ 291 E_(1a)E₂E₃ AlkL E₅ 292 E_(1b)E₂E₃ AlkL E₅ 293 E_(1a)E₂E_(i) AlkL E₅ 294 E_(1b)E₂E_(i) AlkL E₅ 295 E_(1a)E₂E_(ii) AlkL E₅ 296 E_(1b)E₂E_(ii) AlkL E₅ 297 E_(1a)E₂E_(ii)E_(iib) AlkL E₅ 298 E_(1b)E₂E_(ii)E_(iib) AlkL E₅ 299 E_(1a)E₂E₃E_(i) AlkL E₅ 300 E_(1b)E₂E₃E_(i) AlkL E₅ 301 E_(1a)E₂E₃E_(ii) AlkL E₅ 302 E_(1b)E₂E₃E_(ii) AlkL E₅ 303 E_(1a)E₂E₃E_(ii)E_(iib) AlkL E₅ 304 E_(1b)E₂E₃E_(ii)E_(iib) AlkL E₅ 305 E_(1a)E₂E₄ AlkL E₅ 306 E_(1b)E₂E₄ AlkL E₅ 307 E_(1a)E₂E₃E₄ AlkL E₅ 308 E_(1b)E₂E₃E₄ AlkL E₅ 309 E_(1a)E₂E_(i)E₄ AlkL E₅ 310 E_(1b)E₂E_(i)E₄ AlkL E₅ 311 E_(1a)E₂E_(ii)E₄ AlkL E₅ 312 E_(1b)E₂E_(ii)E₄ AlkL E₅ 313 E_(1a)E₂E_(ii)E_(iib)E₄ AlkL E₅ 314 E_(1b)E₂E_(ii)E_(iib)E₄ AlkL E₅ 315 E_(1a)E₂E₃E_(i)E₄ AlkL E₅ 316 E_(1b)E₂E₃E_(i)E₄ AlkL E₅ 317 E_(1a)E₂E₃E_(ii)E₄ AlkL E₅ 318 E_(1b)E₂E₃E_(ii)E₄ AlkL E₅ 319 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkL E₅ 320 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkL E₅ 321 E_(1a)E₂E_(iii) AlkL E₅ 322 E_(1b)E₂E_(iii) AlkL E₅ 323 E_(1a)E₂E₃E_(iii) AlkL E₅ 324 E_(1b)E₂E₃E_(iii) AlkL E₅ 325 E_(1a)E₂E_(iii)E₄ AlkL E₅ 326 E_(1b)E₂E_(iii)E₄ AlkL E₅ 327 E_(1a)E₂E₃E_(iii)E₄ AlkL E₅ 328 E_(1b)E₂E₃E_(iii)E₄ AlkL E₅ 329 E_(1a)E₂E_(iv) AlkL E₅ 330 E_(1b)E₂E_(iv) AlkL E₅ 331 E_(1a)E₂E₃E_(iv) AlkL E₅ 332 E_(1b)E₂E₃E_(iv) AlkL E₅ 333 E_(1a)E₂E_(iv)E₄ AlkL E₅ 334 E_(1b)E₂E_(iv)E₄ AlkL E₅ 335 E_(1a)E₂E₃E_(iv)E₄ AlkL E₅ 336 E_(1b)E₂E₃E_(iv)E₄ AlkL E₅ 337 E_(1a)E₂ AlkL E₄*E₅ 338 E_(1b)E₂ AlkL E₄*E₅ 339 E_(1a)E₂E₃ AlkL E₄*E₅ 340 E_(1b)E₂E₃ AlkL E₄*E₅ 341 E_(1a)E₂E_(i) AlkL E₄*E₅ 342 E_(1b)E₂E_(i) AlkL E₄*E₅ 343 E_(1a)E₂E_(ii) AlkL E₄*E₅ 344 E_(1b)E₂E_(ii) AlkL E₄*E₅ 345 E_(1a)E₂E_(ii)E_(iib) AlkL E₄*E₅ 346 E_(1b)E₂E_(ii)E_(iib) AlkL E₄*E₅ 347 E_(1a)E₂E₃E_(i) AlkL E₄*E₅ 348 E_(1b)E₂E₃E_(i) AlkL E₄*E₅ 349 E_(1a)E₂E₃E_(ii) AlkL E₄*E₅ 350 E_(1b)E₂E₃E_(ii) AlkL E₄*E₅ 351 E_(1a)E₂E₃E_(ii)E_(iib) AlkL E₄*E₅ 352 E_(1b)E₂E₃E_(ii)E_(iib) AlkL E₄*E₅ 353 E_(1a)E₂E₄ AlkL E₄*E₅ 354 E_(1b)E₂E₄ AlkL E₄*E₅ 355 E_(1a)E₂E₃E₄ AlkL E₄*E₅ 356 E_(1b)E₂E₃E₄ AlkL E₄*E₅ 357 E_(1a)E₂E_(i)E₄ AlkL E₄*E₅ 358 E_(1b)E₂E_(i)E₄ AlkL E₄*E₅ 359 E_(1a)E₂E_(ii)E₄ AlkL E₄*E₅ 360 E_(1b)E₂E_(ii)E₄ AlkL E₄*E₅ 361 E_(1a)E₂E_(ii)E_(iib)E₄ AlkL E₄*E₅ 362 E_(1b)E₂E_(ii)E_(iib)E₄ AlkL E₄*E₅ 363 E_(1a)E₂E₃E_(i)E₄ AlkL E₄*E₅ 364 E_(1b)E₂E₃E_(i)E₄ AlkL E₄*E₅ 365 E_(1a)E₂E₃E_(ii)E₄ AlkL E₄*E₅ 366 E_(1b)E₂E₃E_(ii)E₄ AlkL E₄*E₅ 367 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkL E₄*E₅ 368 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkL E₄*E₅ 369 E_(1a)E₂E_(iii) AlkL E₄*E₅ 370 E_(1b)E₂E_(iii) AlkL E₄*E₅ 371 E_(1a)E₂E₃E_(iii) AlkL E₄*E₅ 372 E_(1b)E₂E₃E_(iii) AlkL E₄*E₅ 373 E_(1a)E₂E_(iii)E₄ AlkL E₄*E₅ 374 E_(1b)E₂E_(iii)E₄ AlkL E₄*E₅ 375 E_(1a)E₂E₃E_(iii)E₄ AlkL E₄*E₅ 376 E_(1b)E₂E₃E_(iii)E₄ AlkL E₄*E₅ 377 E_(1a)E₂E_(iv) AlkL E₄*E₅ 378 E_(1b)E₂E_(iv) AlkL E₄*E₅ 379 E_(1a)E₂E₃E_(iv) AlkL E₄*E₅ 380 E_(1b)E₂E₃E_(iv) AlkL E₄*E₅ 381 E_(1a)E₂E_(iv)E₄ AlkL E₄*E₅ 382 E_(1b)E₂E_(iv)E₄ AlkL E₄*E₅ 383 E_(1a)E₂E₃E_(iv)E₄ AlkL E₄*E₅ 384 E_(1b)E₂E₃E_(iv)E₄ AlkL E₄*E₅ 385 E_(1a)E₂ E_(a) 386 E_(1b)E₂ E_(a) 387 E_(1a)E₂E₃ E_(a) 388 E_(1b)E₂E₃ E_(a) 389 E_(1a)E₂E_(i) E_(a) 390 E_(1b)E₂E_(i) E_(a) 391 E_(1a)E₂E_(ii) E_(a) 392 E_(1b)E₂E_(ii) E_(a) 393 E_(1a)E₂E_(ii)E_(iib) E_(a) 394 E_(1b)E₂E_(ii)E_(iib) E_(a) 395 E_(1a)E₂E₃E_(i) E_(a) 396 E_(1b)E₂E₃E_(i) E_(a) 397 E_(1a)E₂E₃E_(ii) E_(a) 398 E_(1b)E₂E₃E_(ii) E_(a) 399 E_(1a)E₂E₃E_(ii)E_(iib) E_(a) 400 E_(1b)E₂E₃E_(ii)E_(iib) E_(a) 401 E_(1a)E₂E₄ E_(a) 402 E_(1b)E₂E₄ E_(a) 403 E_(1a)E₂E₃E₄ E_(a) 404 E_(1b)E₂E₃E₄ E_(a) 405 E_(1a)E₂E_(i)E₄ E_(a) 406 E_(1b)E₂E_(i)E₄ E_(a) 407 E_(1a)E₂E_(ii)E₄ E_(a) 408 E_(1b)E₂E_(ii)E₄ E_(a) 409 E_(1a)E₂E_(ii)E_(iib)E₄ E_(a) 410 E_(1b)E₂E_(ii)E_(iib)E₄ E_(a) 411 E_(1a)E₂E₃E_(i)E₄ E_(a) 412 E_(1b)E₂E₃E_(i)E₄ E_(a) 413 E_(1a)E₂E₃E_(ii)E₄ E_(a) 414 E_(1b)E₂E₃E_(ii)E₄ E_(a) 415 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E_(a) 416 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E_(a) 417 E_(1a)E₂E_(iii) E_(a) 418 E_(1b)E₂E_(iii) E_(a) 419 E_(1a)E₂E₃E_(iii) E_(a) 420 E_(1b)E₂E₃E_(iii) E_(a) 421 E_(1a)E₂E_(iii)E₄ E_(a) 422 E_(1b)E₂E_(iii)E₄ E_(a) 423 E_(1a)E₂E₃E_(iii)E₄ E_(a) 424 E_(1b)E₂E₃E_(iii)E₄ E_(a) 425 E_(1a)E₂E_(iv) E_(a) 426 E_(1b)E₂E_(iv) E_(a) 427 E_(1a)E₂E₃E_(iv) E_(a) 428 E_(1b)E₂E₃E_(iv) E_(a) 429 E_(1a)E₂E_(iv)E₄ E_(a) 430 E_(1b)E₂E_(iv)E₄ E_(a) 431 E_(1a)E₂E₃E_(iv)E₄ E_(a) 432 E_(1b)E₂E₃E_(iv)E₄ E_(a) 433 E_(1a)E₂ E₄* E_(a) 434 E_(1b)E₂ E₄* E_(a) 435 E_(1a)E₂E₃ E₄* E_(a) 436 E_(1b)E₂E₃ E₄* E_(a) 437 E_(1a)E₂E_(i) E₄* E_(a) 438 E_(1b)E₂E_(i) E₄* E_(a) 439 E_(1a)E₂E_(ii) E₄* E_(a) 440 E_(1b)E₂E_(ii) E₄* E_(a) 441 E_(1a)E₂E_(ii)E_(iib) E₄* E_(a) 442 E_(1b)E₂E_(ii)E_(iib) E₄* E_(a) 443 E_(1a)E₂E₃E_(i) E₄* E_(a) 444 E_(1b)E₂E₃E_(i) E₄* E_(a) 445 E_(1a)E₂E₃E_(ii) E₄* E_(a) 446 E_(1b)E₂E₃E_(ii) E₄* E_(a) 447 E_(1a)E₂E₃E_(ii)E_(iib) E₄* E_(a) 448 E_(1b)E₂E₃E_(ii)E_(iib) E₄* E_(a) 449 E_(1a)E₂E₄ E₄* E_(a) 450 E_(1b)E₂E₄ E₄* E_(a) 451 E_(1a)E₂E₃E₄ E₄* E_(a) 452 E_(1b)E₂E₃E₄ E₄* E_(a) 453 E_(1a)E₂E_(i)E₄ E₄* E_(a) 454 E_(1b)E₂E_(i)E₄ E₄* E_(a) 455 E_(1a)E₂E_(ii)E₄ E₄* E_(a) 456 E_(1b)E₂E_(ii)E₄ E₄* E_(a) 457 E_(1a)E₂E_(ii)E_(iib)E₄ E₄* E_(a) 458 E_(1b)E₂E_(ii)E_(iib)E₄ E₄* E_(a) 459 E_(1a)E₂E₃E_(i)E₄ E₄* E_(a) 460 E_(1b)E₂E₃E_(i)E₄ E₄* E_(a) 461 E_(1a)E₂E₃E_(ii)E₄ E₄* E_(a) 462 E_(1b)E₂E₃E_(ii)E₄ E₄* E_(a) 463 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E₄* E_(a) 464 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E₄* E_(a) 465 E_(1a)E₂E_(iii) E₄* E_(a) 466 E_(1b)E₂E_(iii) E₄* E_(a) 467 E_(1a)E₂E₃E_(iii) E₄* E_(a) 468 E_(1b)E₂E₃E_(iii) E₄* E_(a) 469 E_(1a)E₂E_(iii)E₄ E₄* E_(a) 470 E_(1b)E₂E_(iii)E₄ E₄* E_(a) 471 E_(1a)E₂E₃E_(iii)E₄ E₄* E_(a) 472 E_(1b)E₂E₃E_(iii)E₄ E₄* E_(a) 473 E_(1a)E₂E_(iv) E₄* E_(a) 474 E_(1b)E₂E_(iv) E₄* E_(a) 475 E_(1a)E₂E₃E_(iv) E₄* E_(a) 476 E_(1b)E₂E₃E_(iv) E₄* E_(a) 477 E_(1a)E₂E_(iv)E₄ E₄* E_(a) 478 E_(1b)E₂E_(iv)E₄ E₄* E_(a) 479 E_(1a)E₂E₃E_(iv)E₄ E₄* E_(a) 480 E_(1b)E₂E₃E_(iv)E₄ E₄* E_(a) 481 E_(1a)E₂ E₅ E_(a) 482 E_(1b)E₂ E₅ E_(a) 483 E_(1a)E₂E₃ E₅ E_(a) 484 E_(1b)E₂E₃ E₅ E_(a) 485 E_(1a)E₂E_(i) E₅ E_(a) 486 E_(1b)E₂E_(i) E₅ E_(a) 487 E_(1a)E₂E_(ii) E₅ E_(a) 488 E_(1b)E₂E_(ii) E₅ E_(a) 489 E_(1a)E₂E_(ii)E_(iib) E₅ E_(a) 490 E_(1b)E₂E_(ii)E_(iib) E₅ E_(a) 491 E_(1a)E₂E₃E_(i) E₅ E_(a) 492 E_(1b)E₂E₃E_(i) E₅ E_(a) 493 E_(1a)E₂E₃E_(ii) E₅ E_(a) 494 E_(1b)E₂E₃E_(ii) E₅ E_(a) 495 E_(1a)E₂E₃E_(ii)E_(iib) E₅ E_(a) 496 E_(1b)E₂E₃E_(ii)E_(iib) E₅ E_(a) 497 E_(1a)E₂E₄ E₅ E_(a) 498 E_(1b)E₂E₄ E₅ E_(a) 499 E_(1a)E₂E₃E₄ E₅ E_(a) 500 E_(1b)E₂E₃E₄ E₅ E_(a) 501 E_(1a)E₂E_(i)E₄ E₅ E_(a) 502 E_(1b)E₂E_(i)E₄ E₅ E_(a) 503 E_(1a)E₂E_(ii)E₄ E₅ E_(a) 504 E_(1b)E₂E_(ii)E₄ E₅ E_(a) 505 E_(1a)E₂E_(ii)E_(iib)E₄ E₅ E_(a) 506 E_(1b)E₂E_(ii)E_(iib)E₄ E₅ E_(a) 507 E_(1a)E₂E₃E_(i)E₄ E₅ E_(a) 508 E_(1b)E₂E₃E_(i)E₄ E₅ E_(a) 509 E_(1a)E₂E₃E_(ii)E₄ E₅ E_(a) 510 E_(1b)E₂E₃E_(ii)E₄ E₅ E_(a) 511 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E₅ E_(a) 512 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E₅ E_(a) 513 E_(1a)E₂E_(iii) E₅ E_(a) 514 E_(1b)E₂E_(iii) E₅ E_(a) 515 E_(1a)E₂E₃E_(iii) E₅ E_(a) 516 E_(1b)E₂E₃E_(iii) E₅ E_(a) 517 E_(1a)E₂E_(iii)E₄ E₅ E_(a) 518 E_(1b)E₂E_(iii)E₄ E₅ E_(a) 519 E_(1a)E₂E₃E_(iii)E₄ E₅ E_(a) 520 E_(1b)E₂E₃E_(iii)E₄ E₅ E_(a) 521 E_(1a)E₂E_(iv) E₅ E_(a) 522 E_(1b)E₂E_(iv) E₅ E_(a) 523 E_(1a)E₂E₃E_(iv) E₅ E_(a) 524 E_(1b)E₂E₃E_(iv) E₅ E_(a) 525 E_(1a)E₂E_(iv)E₄ E₅ E_(a) 526 E_(1b)E₂E_(iv)E₄ E₅ E_(a) 527 E_(1a)E₂E₃E_(iv)E₄ E₅ E_(a) 528 E_(1b)E₂E₃E_(iv)E₄ E₅ E_(a) 529 E_(1a)E₂ E₄*E₅ E_(a) 530 E_(1b)E₂ E₄*E₅ E_(a) 531 E_(1a)E₂E₃ E₄*E₅ E_(a) 532 E_(1b)E₂E₃ E₄*E₅ E_(a) 533 E_(1a)E₂E_(i) E₄*E₅ E_(a) 534 E_(1b)E₂E_(i) E₄*E₅ E_(a) 535 E_(1a)E₂E_(ii) E₄*E₅ E_(a) 536 E_(1b)E₂E_(ii) E₄*E₅ E_(a) 537 E_(1a)E₂E_(ii)E_(iib) E₄*E₅ E_(a) 538 E_(1b)E₂E_(ii)E_(iib) E₄*E₅ E_(a) 539 E_(1a)E₂E₃E_(i) E₄*E₅ E_(a) 540 E_(1b)E₂E₃E_(i) E₄*E₅ E_(a) 541 E_(1a)E₂E₃E_(ii) E₄*E₅ E_(a) 542 E_(1b)E₂E₃E_(ii) E₄*E₅ E_(a) 543 E_(1a)E₂E₃E_(ii)E_(iib) E₄*E₅ E_(a) 544 E_(1b)E₂E₃E_(ii)E_(iib) E₄*E₅ E_(a) 545 E_(1a)E₂E₄ E₄*E₅ E_(a) 546 E_(1b)E₂E₄ E₄*E₅ E_(a) 547 E_(1a)E₂E₃E₄ E₄*E₅ E_(a) 548 E_(1b)E₂E₃E₄ E₄*E₅ E_(a) 549 E_(1a)E₂E_(i)E₄ E₄*E₅ E_(a) 550 E_(1b)E₂E_(i)E₄ E₄*E₅ E_(a) 551 E_(1a)E₂E_(ii)E₄ E₄*E₅ E_(a) 552 E_(1b)E₂E_(ii)E₄ E₄*E₅ E_(a) 553 E_(1a)E₂E_(ii)E_(iib)E₄ E₄*E₅ E_(a) 554 E_(1b)E₂E_(ii)E_(iib)E₄ E₄*E₅ E_(a) 555 E_(1a)E₂E₃E_(i)E₄ E₄*E₅ E_(a) 556 E_(1b)E₂E₃E_(i)E₄ E₄*E₅ E_(a) 557 E_(1a)E₂E₃E_(ii)E₄ E₄*E₅ E_(a) 558 E_(1b)E₂E₃E_(ii)E₄ E₄*E₅ E_(a) 559 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E₄*E₅ E_(a) 560 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E₄*E₅ E_(a) 561 E_(1a)E₂E_(iii) E₄*E₅ E_(a) 562 E_(1b)E₂E_(iii) E₄*E₅ E_(a) 563 E_(1a)E₂E₃E_(iii) E₄*E₅ E_(a) 564 E_(1b)E₂E₃E_(iii) E₄*E₅ E_(a) 565 E_(1a)E₂E_(iii)E₄ E₄*E₅ E_(a) 566 E_(1b)E₂E_(iii)E₄ E₄*E₅ E_(a) 567 E_(1a)E₂E₃E_(iii)E₄ E₄*E₅ E_(a) 568 E_(1b)E₂E₃E_(iii)E₄ E₄*E₅ E_(a) 569 E_(1a)E₂E_(iv) E₄*E₅ E_(a) 570 E_(1b)E₂E_(iv) E₄*E₅ E_(a) 571 E_(1a)E₂E₃E_(iv) E₄*E₅ E_(a) 572 E_(1b)E₂E₃E_(iv) E₄*E₅ E_(a) 573 E_(1a)E₂E_(iv)E₄ E₄*E₅ E_(a) 574 E_(1b)E₂E_(iv)E₄ E₄*E₅ E_(a) 575 E_(1a)E₂E₃E_(iv)E₄ E₄*E₅ E_(a) 576 E_(1b)E₂E₃E_(iv)E₄ E₄*E₅ E_(a) 577 E_(1a)E₂ AlkL E_(a) 578 E_(1b)E₂ AlkL E_(a) 579 E_(1a)E₂E₃ AlkL E_(a) 580 E_(1b)E₂E₃ AlkL E_(a) 581 E_(1a)E₂E_(i) AlkL E_(a) 582 E_(1b)E₂E_(i) AlkL E_(a) 583 E_(1a)E₂E_(ii) AlkL E_(a) 584 E_(1b)E₂E_(ii) AlkL E_(a) 585 E_(1a)E₂E_(ii)E_(iib) AlkL E_(a) 586 E_(1b)E₂E_(ii)E_(iib) AlkL E_(a) 587 E_(1a)E₂E₃E_(i) AlkL E_(a) 588 E_(1b)E₂E₃E_(i) AlkL E_(a) 589 E_(1a)E₂E₃E_(ii) AlkL E_(a) 590 E_(1b)E₂E₃E_(ii) AlkL E_(a) 591 E_(1a)E₂E₃E_(ii)E_(iib) AlkL E_(a) 592 E_(1b)E₂E₃E_(ii)E_(iib) AlkL E_(a) 593 E_(1a)E₂E₄ AlkL E_(a) 594 E_(1b)E₂E₄ AlkL E_(a) 595 E_(1a)E₂E₃E₄ AlkL E_(a) 596 E_(1b)E₂E₃E₄ AlkL E_(a) 597 E_(1a)E₂E_(i)E₄ AlkL E_(a) 598 E_(1b)E₂E_(i)E₄ AlkL E_(a) 599 E_(1a)E₂E_(ii)E₄ AlkL E_(a) 600 E_(1b)E₂E_(ii)E₄ AlkL E_(a) 601 E_(1a)E₂E_(ii)E_(iib)E₄ AlkL E_(a) 602 E_(1b)E₂E_(ii)E_(iib)E₄ AlkL E_(a) 603 E_(1a)E₂E₃E_(i)E₄ AlkL E_(a) 604 E_(1b)E₂E₃E_(i)E₄ AlkL E_(a) 605 E_(1a)E₂E₃E_(ii)E₄ AlkL E_(a) 606 E_(1b)E₂E₃E_(ii)E₄ AlkL E_(a) 607 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkL E_(a) 608 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkL E_(a) 609 E_(1a)E₂E_(iii) AlkL E_(a) 610 E_(1b)E₂E_(iii) AlkL E_(a) 611 E_(1a)E₂E₃E_(iii) AlkL E_(a) 612 E_(1b)E₂E₃E_(iii) AlkL E_(a) 613 E_(1a)E₂E_(iii)E₄ AlkL E_(a) 614 E_(1b)E₂E_(iii)E₄ AlkL E_(a) 615 E_(1a)E₂E₃E_(iii)E₄ AlkL E_(a) 616 E_(1b)E₂E₃E_(iii)E₄ AlkL E_(a) 617 E_(1a)E₂E_(iv) AlkL E_(a) 618 E_(1b)E₂E_(iv) AlkL E_(a) 619 E_(1a)E₂E₃E_(iv) AlkL E_(a) 620 E_(1b)E₂E₃E_(iv) AlkL E_(a) 621 E_(1a)E₂E_(iv)E₄ AlkL E_(a) 622 E_(1b)E₂E_(iv)E₄ AlkL E_(a) 623 E_(1a)E₂E₃E_(iv)E₄ AlkL E_(a) 624 E_(1b)E₂E₃E_(iv)E₄ AlkL E_(a) 625 E_(1a)E₂ AlkL E₄* E_(a) 626 E_(1b)E₂ AlkL E₄* E_(a) 627 E_(1a)E₂E₃ AlkL E₄* E_(a) 628 E_(1b)E₂E₃ AlkL E₄* E_(a) 629 E_(1a)E₂E_(i) AlkL E₄* E_(a) 630 E_(1b)E₂E_(i) AlkL E₄* E_(a) 631 E_(1a)E₂E_(ii) AlkL E₄* E_(a) 632 E_(1b)E₂E_(ii) AlkL E₄* E_(a) 633 E_(1a)E₂E_(ii)E_(iib) AlkL E₄* E_(a) 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E_(1a)E₂E₄ AlkL E₅ E_(a) 690 E_(1b)E₂E₄ AlkL E₅ E_(a) 691 E_(1a)E₂E₃E₄ AlkL E₅ E_(a) 692 E_(1b)E₂E₃E₄ AlkL E₅ E_(a) 693 E_(1a)E₂E_(i)E₄ AlkL E₅ E_(a) 694 E_(1b)E₂E_(i)E₄ AlkL E₅ E_(a) 695 E_(1a)E₂E_(ii)E₄ AlkL E₅ E_(a) 696 E_(1b)E₂E_(ii)E₄ AlkL E₅ E_(a) 697 E_(1a)E₂E_(ii)E_(iib)E₄ AlkL E₅ E_(a) 698 E_(1b)E₂E_(ii)E_(iib)E₄ AlkL E₅ E_(a) 699 E_(1a)E₂E₃E_(i)E₄ AlkL E₅ E_(a) 700 E_(1b)E₂E₃E_(i)E₄ AlkL E₅ E_(a) 701 E_(1a)E₂E₃E_(ii)E₄ AlkL E₅ E_(a) 702 E_(1b)E₂E₃E_(ii)E₄ AlkL E₅ E_(a) 703 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkL E₅ E_(a) 704 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkL E₅ E_(a) 705 E_(1a)E₂E_(iii) AlkL E₅ E_(a) 706 E_(1b)E₂E_(iii) AlkL E₅ E_(a) 707 E_(1a)E₂E₃E_(iii) AlkL E₅ E_(a) 708 E_(1b)E₂E₃E_(iii) AlkL E₅ E_(a) 709 E_(1a)E₂E_(iii)E₄ AlkL E₅ E_(a) 710 E_(1b)E₂E_(iii)E₄ AlkL E₅ E_(a) 711 E_(1a)E₂E₃E_(iii)E₄ AlkL E₅ E_(a) 712 E_(1b)E₂E₃E_(iii)E₄ AlkL E₅ E_(a) 713 E_(1a)E₂E_(iv) AlkL E₅ E_(a) 714 E_(1b)E₂E_(iv) AlkL E₅ E_(a) 715 E_(1a)E₂E₃E_(iv) AlkL E₅ E_(a) 716 E_(1b)E₂E₃E_(iv) AlkL E₅ E_(a) 717 E_(1a)E₂E_(iv)E₄ AlkL E₅ E_(a) 718 E_(1b)E₂E_(iv)E₄ AlkL E₅ E_(a) 719 E_(1a)E₂E₃E_(iv)E₄ AlkL E₅ E_(a) 720 E_(1b)E₂E₃E_(iv)E₄ AlkL E₅ E_(a) 721 E_(1a)E₂ AlkL E₄*E₅ E_(a) 722 E_(1b)E₂ AlkL E₄*E₅ E_(a) 723 E_(1a)E₂E₃ AlkL E₄*E₅ E_(a) 724 E_(1b)E₂E₃ AlkL E₄*E₅ E_(a) 725 E_(1a)E₂E_(i) AlkL E₄*E₅ E_(a) 726 E_(1b)E₂E_(i) AlkL E₄*E₅ E_(a) 727 E_(1a)E₂E_(ii) AlkL E₄*E₅ E_(a) 728 E_(1b)E₂E_(ii) AlkL E₄*E₅ E_(a) 729 E_(1a)E₂E_(ii)E_(iib) AlkL E₄*E₅ E_(a) 730 E_(1b)E₂E_(ii)E_(iib) AlkL E₄*E₅ E_(a) 731 E_(1a)E₂E₃E_(i) AlkL E₄*E₅ E_(a) 732 E_(1b)E₂E₃E_(i) AlkL E₄*E₅ E_(a) 733 E_(1a)E₂E₃E_(ii) AlkL E₄*E₅ E_(a) 734 E_(1b)E₂E₃E_(ii) AlkL E₄*E₅ E_(a) 735 E_(1a)E₂E₃E_(ii)E_(iib) AlkL E₄*E₅ E_(a) 736 E_(1b)E₂E₃E_(ii)E_(iib) AlkL E₄*E₅ E_(a) 737 E_(1a)E₂E₄ AlkL E₄*E₅ E_(a) 738 E_(1b)E₂E₄ AlkL E₄*E₅ E_(a) 739 E_(1a)E₂E₃E₄ AlkL E₄*E₅ E_(a) 740 E_(1b)E₂E₃E₄ AlkL E₄*E₅ E_(a) 741 E_(1a)E₂E_(i)E₄ AlkL E₄*E₅ E_(a) 742 E_(1b)E₂E_(i)E₄ AlkL E₄*E₅ E_(a) 743 E_(1a)E₂E_(ii)E₄ AlkL E₄*E₅ E_(a) 744 E_(1b)E₂E_(ii)E₄ AlkL E₄*E₅ E_(a) 745 E_(1a)E₂E_(ii)E_(iib)E₄ AlkL E₄*E₅ E_(a) 746 E_(1b)E₂E_(ii)E_(iib)E₄ AlkL E₄*E₅ E_(a) 747 E_(1a)E₂E₃E_(i)E₄ AlkL E₄*E₅ E_(a) 748 E_(1b)E₂E₃E_(i)E₄ AlkL E₄*E₅ E_(a) 749 E_(1a)E₂E₃E_(ii)E₄ AlkL E₄*E₅ E_(a) 750 E_(1b)E₂E₃E_(ii)E₄ AlkL E₄*E₅ E_(a) 751 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkL E₄*E₅ E_(a) 752 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkL E₄*E₅ E_(a) 753 E_(1a)E₂E_(iii) AlkL E₄*E₅ E_(a) 754 E_(1b)E₂E_(iii) AlkL E₄*E₅ E_(a) 755 E_(1a)E₂E₃E_(iii) AlkL E₄*E₅ E_(a) 756 E_(1b)E₂E₃E_(iii) AlkL E₄*E₅ E_(a) 757 E_(1a)E₂E_(iii)E₄ AlkL E₄*E₅ E_(a) 758 E_(1b)E₂E_(iii)E₄ AlkL E₄*E₅ E_(a) 759 E_(1a)E₂E₃E_(iii)E₄ AlkL E₄*E₅ E_(a) 760 E_(1b)E₂E₃E_(iii)E₄ AlkL E₄*E₅ E_(a) 761 E_(1a)E₂E_(iv) AlkL E₄*E₅ E_(a) 762 E_(1b)E₂E_(iv) AlkL E₄*E₅ E_(a) 763 E_(1a)E₂E₃E_(iv) AlkL E₄*E₅ E_(a) 764 E_(1b)E₂E₃E_(iv) AlkL E₄*E₅ E_(a) 765 E_(1a)E₂E_(iv)E₄ AlkL E₄*E₅ E_(a) 766 E_(1b)E₂E_(iv)E₄ AlkL E₄*E₅ E_(a) 767 E_(1a)E₂E₃E_(iv)E₄ AlkL E₄*E₅ E_(a) 768 E_(1b)E₂E₃E_(iv)E₄ AlkL E₄*E₅ E_(a) 769 E_(1a)E₂ E_(b) 770 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E_(1a)E₂E_(ii)E_(iib) E₅ E_(b) 874 E_(1b)E₂E_(ii)E_(iib) E₅ E_(b) 875 E_(1a)E₂E₃E_(i) E₅ E_(b) 876 E_(1b)E₂E₃E_(i) E₅ E_(b) 877 E_(1a)E₂E₃E_(ii) E₅ E_(b) 878 E_(1b)E₂E₃E_(ii) E₅ E_(b) 879 E_(1a)E₂E₃E_(ii)E_(iib) E₅ E_(b) 880 E_(1b)E₂E₃E_(ii)E_(iib) E₅ E_(b) 881 E_(1a)E₂E₄ E₅ E_(b) 882 E_(1b)E₂E₄ E₅ E_(b) 883 E_(1a)E₂E₃E₄ E₅ E_(b) 884 E_(1b)E₂E₃E₄ E₅ E_(b) 885 E_(1a)E₂E_(i)E₄ E₅ E_(b) 886 E_(1b)E₂E_(i)E₄ E₅ E_(b) 887 E_(1a)E₂E_(ii)E₄ E₅ E_(b) 888 E_(1b)E₂E_(ii)E₄ E₅ E_(b) 889 E_(1a)E₂E_(ii)E_(iib)E₄ E₅ E_(b) 890 E_(1b)E₂E_(ii)E_(iib)E₄ E₅ E_(b) 891 E_(1a)E₂E₃E_(i)E₄ E₅ E_(b) 892 E_(1b)E₂E₃E_(i)E₄ E₅ E_(b) 893 E_(1a)E₂E₃E_(ii)E₄ E₅ E_(b) 894 E_(1b)E₂E₃E_(ii)E₄ E₅ E_(b) 895 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E₅ E_(b) 896 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E₅ E_(b) 897 E_(1a)E₂E_(iii) E₅ E_(b) 898 E_(1b)E₂E_(iii) E₅ E_(b) 899 E_(1a)E₂E₃E_(iii) E₅ E_(b) 900 E_(1b)E₂E₃E_(iii) E₅ E_(b) 901 E_(1a)E₂E_(iii)E₄ E₅ E_(b) 902 E_(1b)E₂E_(iii)E₄ E₅ E_(b) 903 E_(1a)E₂E₃E_(iii)E₄ E₅ E_(b) 904 E_(1b)E₂E₃E_(iii)E₄ E₅ E_(b) 905 E_(1a)E₂E_(iv) E₅ E_(b) 906 E_(1b)E₂E_(iv) E₅ E_(b) 907 E_(1a)E₂E₃E_(iv) E₅ E_(b) 908 E_(1b)E₂E₃E_(iv) E₅ E_(b) 909 E_(1a)E₂E_(iv)E₄ E₅ E_(b) 910 E_(1b)E₂E_(iv)E₄ E₅ E_(b) 911 E_(1a)E₂E₃E_(iv)E₄ E₅ E_(b) 912 E_(1b)E₂E₃E_(iv)E₄ E₅ E_(b) 913 E_(1a)E₂ E₄*E₅ E_(b) 914 E_(1b)E₂ E₄*E₅ E_(b) 915 E_(1a)E₂E₃ E₄*E₅ E_(b) 916 E_(1b)E₂E₃ E₄*E₅ E_(b) 917 E_(1a)E₂E_(i) E₄*E₅ E_(b) 918 E_(1b)E₂E_(i) E₄*E₅ E_(b) 919 E_(1a)E₂E_(ii) E₄*E₅ E_(b) 920 E_(1b)E₂E_(ii) E₄*E₅ E_(b) 921 E_(1a)E₂E_(ii)E_(iib) E₄*E₅ E_(b) 922 E_(1b)E₂E_(ii)E_(iib) E₄*E₅ E_(b) 923 E_(1a)E₂E₃E_(i) E₄*E₅ E_(b) 924 E_(1b)E₂E₃E_(i) E₄*E₅ E_(b) 925 E_(1a)E₂E₃E_(ii) E₄*E₅ E_(b) 926 E_(1b)E₂E₃E_(ii) E₄*E₅ E_(b) 927 E_(1a)E₂E₃E_(ii)E_(iib) E₄*E₅ E_(b) 928 E_(1b)E₂E₃E_(ii)E_(iib) E₄*E₅ E_(b) 929 E_(1a)E₂E₄ E₄*E₅ E_(b) 930 E_(1b)E₂E₄ E₄*E₅ E_(b) 931 E_(1a)E₂E₃E₄ E₄*E₅ E_(b) 932 E_(1b)E₂E₃E₄ E₄*E₅ E_(b) 933 E_(1a)E₂E_(i)E₄ E₄*E₅ E_(b) 934 E_(1b)E₂E_(i)E₄ E₄*E₅ E_(b) 935 E_(1a)E₂E_(ii)E₄ E₄*E₅ E_(b) 936 E_(1b)E₂E_(ii)E₄ E₄*E₅ E_(b) 937 E_(1a)E₂E_(ii)E_(iib)E₄ E₄*E₅ E_(b) 938 E_(1b)E₂E_(ii)E_(iib)E₄ E₄*E₅ E_(b) 939 E_(1a)E₂E₃E_(i)E₄ E₄*E₅ E_(b) 940 E_(1b)E₂E₃E_(i)E₄ E₄*E₅ E_(b) 941 E_(1a)E₂E₃E_(ii)E₄ E₄*E₅ E_(b) 942 E_(1b)E₂E₃E_(ii)E₄ E₄*E₅ E_(b) 943 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E₄*E₅ E_(b) 944 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E₄*E₅ E_(b) 945 E_(1a)E₂E_(iii) E₄*E₅ E_(b) 946 E_(1b)E₂E_(iii) E₄*E₅ E_(b) 947 E_(1a)E₂E₃E_(iii) E₄*E₅ E_(b) 948 E_(1b)E₂E₃E_(iii) E₄*E₅ E_(b) 949 E_(1a)E₂E_(iii)E₄ E₄*E₅ E_(b) 950 E_(1b)E₂E_(iii)E₄ E₄*E₅ E_(b) 951 E_(1a)E₂E₃E_(iii)E₄ E₄*E₅ E_(b) 952 E_(1b)E₂E₃E_(iii)E₄ E₄*E₅ E_(b) 953 E_(1a)E₂E_(iv) E₄*E₅ E_(b) 954 E_(1b)E₂E_(iv) E₄*E₅ E_(b) 955 E_(1a)E₂E₃E_(iv) E₄*E₅ E_(b) 956 E_(1b)E₂E₃E_(iv) E₄*E₅ E_(b) 957 E_(1a)E₂E_(iv)E₄ E₄*E₅ E_(b) 958 E_(1b)E₂E_(iv)E₄ E₄*E₅ E_(b) 959 E_(1a)E₂E₃E_(iv)E₄ E₄*E₅ E_(b) 960 E_(1b)E₂E₃E_(iv)E₄ E₄*E₅ E_(b) 961 E_(1a)E₂ AlkL E_(b) 962 E_(1b)E₂ AlkL E_(b) 963 E_(1a)E₂E₃ AlkL E_(b) 964 E_(1b)E₂E₃ AlkL E_(b) 965 E_(1a)E₂E_(i) AlkL E_(b) 966 E_(1b)E₂E_(i) AlkL E_(b) 967 E_(1a)E₂E_(ii) AlkL E_(b) 968 E_(1b)E₂E_(ii) AlkL E_(b) 969 E_(1a)E₂E_(ii)E_(iib) AlkL E_(b) 970 E_(1b)E₂E_(ii)E_(iib) AlkL E_(b) 971 E_(1a)E₂E₃E_(i) AlkL E_(b) 972 E_(1b)E₂E₃E_(i) AlkL E_(b) 973 E_(1a)E₂E₃E_(ii) AlkL E_(b) 974 E_(1b)E₂E₃E_(ii) AlkL E_(b) 975 E_(1a)E₂E₃E_(ii)E_(iib) AlkL E_(b) 976 E_(1b)E₂E₃E_(ii)E_(iib) AlkL E_(b) 977 E_(1a)E₂E₄ AlkL E_(b) 978 E_(1b)E₂E₄ AlkL E_(b) 979 E_(1a)E₂E₃E₄ AlkL E_(b) 980 E_(1b)E₂E₃E₄ AlkL E_(b) 981 E_(1a)E₂E_(i)E₄ AlkL E_(b) 982 E_(1b)E₂E_(i)E₄ AlkL E_(b) 983 E_(1a)E₂E_(ii)E₄ AlkL E_(b) 984 E_(1b)E₂E_(ii)E₄ AlkL E_(b) 985 E_(1a)E₂E_(ii)E_(iib)E₄ AlkL E_(b) 986 E_(1b)E₂E_(ii)E_(iib)E₄ AlkL E_(b) 987 E_(1a)E₂E₃E_(i)E₄ AlkL E_(b) 988 E_(1b)E₂E₃E_(i)E₄ AlkL E_(b) 989 E_(1a)E₂E₃E_(ii)E₄ AlkL E_(b) 990 E_(1b)E₂E₃E_(ii)E₄ AlkL E_(b) 991 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkL E_(b) 992 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkL E_(b) 993 E_(1a)E₂E_(iii) AlkL E_(b) 994 E_(1b)E₂E_(iii) AlkL E_(b) 995 E_(1a)E₂E₃E_(iii) AlkL E_(b) 996 E_(1b)E₂E₃E_(iii) AlkL E_(b) 997 E_(1a)E₂E_(iii)E₄ AlkL E_(b) 998 E_(1b)E₂E_(iii)E₄ AlkL E_(b) 999 E_(1a)E₂E₃E_(iii)E₄ AlkL E_(b) 1000 E_(1b)E₂E₃E_(iii)E₄ AlkL E_(b) 1001 E_(1a)E₂E_(iv) AlkL E_(b) 1002 E_(1b)E₂E_(iv) AlkL E_(b) 1003 E_(1a)E₂E₃E_(iv) AlkL E_(b) 1004 E_(1b)E₂E₃E_(iv) AlkL E_(b) 1005 E_(1a)E₂E_(iv)E₄ AlkL E_(b) 1006 E_(1b)E₂E_(iv)E₄ AlkL E_(b) 1007 E_(1a)E₂E₃E_(iv)E₄ AlkL E_(b) 1008 E_(1b)E₂E₃E_(iv)E₄ AlkL E_(b) 1009 E_(1a)E₂ AlkL E₄* E_(b) 1010 E_(1b)E₂ AlkL E₄* E_(b) 1011 E_(1a)E₂E₃ AlkL E₄* E_(b) 1012 E_(1b)E₂E₃ AlkL E₄* E_(b) 1013 E_(1a)E₂E_(i) AlkL E₄* E_(b) 1014 E_(1b)E₂E_(i) AlkL E₄* E_(b) 1015 E_(1a)E₂E_(ii) AlkL E₄* E_(b) 1016 E_(1b)E₂E_(ii) AlkL E₄* E_(b) 1017 E_(1a)E₂E_(ii)E_(iib) AlkL E₄* E_(b) 1018 E_(1b)E₂E_(ii)E_(iib) AlkL E₄* E_(b) 1019 E_(1a)E₂E₃E_(i) AlkL E₄* E_(b) 1020 E_(1b)E₂E₃E_(i) AlkL E₄* E_(b) 1021 E_(1a)E₂E₃E_(ii) AlkL E₄* E_(b) 1022 E_(1b)E₂E₃E_(ii) AlkL E₄* E_(b) 1023 E_(1a)E₂E₃E_(ii)E_(iib) AlkL E₄* E_(b) 1024 E_(1b)E₂E₃E_(ii)E_(iib) AlkL E₄* E_(b) 1025 E_(1a)E₂E₄ AlkL E₄* E_(b) 1026 E_(1b)E₂E₄ AlkL E₄* E_(b) 1027 E_(1a)E₂E₃E₄ AlkL E₄* E_(b) 1028 E_(1b)E₂E₃E₄ AlkL E₄* E_(b) 1029 E_(1a)E₂E_(i)E₄ AlkL E₄* E_(b) 1030 E_(1b)E₂E_(i)E₄ AlkL E₄* E_(b) 1031 E_(1a)E₂E_(ii)E₄ AlkL E₄* E_(b) 1032 E_(1b)E₂E_(ii)E₄ AlkL E₄* E_(b) 1033 E_(1a)E₂E_(ii)E_(iib)E₄ AlkL E₄* E_(b) 1034 E_(1b)E₂E_(ii)E_(iib)E₄ AlkL E₄* E_(b) 1035 E_(1a)E₂E₃E_(i)E₄ AlkL E₄* E_(b) 1036 E_(1b)E₂E₃E_(i)E₄ AlkL E₄* E_(b) 1037 E_(1a)E₂E₃E_(ii)E₄ AlkL E₄* E_(b) 1038 E_(1b)E₂E₃E_(ii)E₄ AlkL E₄* E_(b) 1039 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkL E₄* E_(b) 1040 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkL E₄* E_(b) 1041 E_(1a)E₂E_(iii) AlkL E₄* E_(b) 1042 E_(1b)E₂E_(iii) AlkL E₄* E_(b) 1043 E_(1a)E₂E₃E_(iii) AlkL E₄* E_(b) 1044 E_(1b)E₂E₃E_(iii) AlkL E₄* E_(b) 1045 E_(1a)E₂E_(iii)E₄ AlkL E₄* E_(b) 1046 E_(1b)E₂E_(iii)E₄ AlkL E₄* E_(b) 1047 E_(1a)E₂E₃E_(iii)E₄ AlkL E₄* E_(b) 1048 E_(1b)E₂E₃E_(iii)E₄ AlkL E₄* E_(b) 1049 E_(1a)E₂E_(iv) AlkL E₄* E_(b) 1050 E_(1b)E₂E_(iv) AlkL E₄* E_(b) 1051 E_(1a)E₂E₃E_(iv) AlkL E₄* E_(b) 1052 E_(1b)E₂E₃E_(iv) AlkL E₄* E_(b) 1053 E_(1a)E₂E_(iv)E₄ AlkL E₄* E_(b) 1054 E_(1b)E₂E_(iv)E₄ AlkL E₄* E_(b) 1055 E_(1a)E₂E₃E_(iv)E₄ AlkL E₄* E_(b) 1056 E_(1b)E₂E₃E_(iv)E₄ AlkL E₄* E_(b) 1057 E_(1a)E₂ AlkL E₅ E_(b) 1058 E_(1b)E₂ AlkL E₅ E_(b) 1059 E_(1a)E₂E₃ AlkL E₅ E_(b) 1060 E_(1b)E₂E₃ AlkL E₅ E_(b) 1061 E_(1a)E₂E_(i) AlkL E₅ E_(b) 1062 E_(1b)E₂E_(i) AlkL E₅ E_(b) 1063 E_(1a)E₂E_(ii) AlkL E₅ E_(b) 1064 E_(1b)E₂E_(ii) AlkL E₅ E_(b) 1065 E_(1a)E₂E_(ii)E_(iib) AlkL E₅ E_(b) 1066 E_(1b)E₂E_(ii)E_(iib) AlkL E₅ E_(b) 1067 E_(1a)E₂E₃E_(i) AlkL E₅ E_(b) 1068 E_(1b)E₂E₃E_(i) AlkL E₅ E_(b) 1069 E_(1a)E₂E₃E_(ii) AlkL E₅ E_(b) 1070 E_(1b)E₂E₃E_(ii) AlkL E₅ E_(b) 1071 E_(1a)E₂E₃E_(ii)E_(iib) AlkL E₅ E_(b) 1072 E_(1b)E₂E₃E_(ii)E_(iib) AlkL E₅ E_(b) 1073 E_(1a)E₂E₄ AlkL E₅ E_(b) 1074 E_(1b)E₂E₄ AlkL E₅ E_(b) 1075 E_(1a)E₂E₃E₄ AlkL E₅ E_(b) 1076 E_(1b)E₂E₃E₄ AlkL E₅ E_(b) 1077 E_(1a)E₂E_(i)E₄ AlkL E₅ E_(b) 1078 E_(1b)E₂E_(i)E₄ AlkL E₅ E_(b) 1079 E_(1a)E₂E_(ii)E₄ AlkL E₅ E_(b) 1080 E_(1b)E₂E_(ii)E₄ AlkL E₅ E_(b) 1081 E_(1a)E₂E_(ii)E_(iib)E₄ AlkL E₅ E_(b) 1082 E_(1b)E₂E_(ii)E_(iib)E₄ AlkL E₅ E_(b) 1083 E_(1a)E₂E₃E_(i)E₄ AlkL E₅ E_(b) 1084 E_(1b)E₂E₃E_(i)E₄ AlkL E₅ E_(b) 1085 E_(1a)E₂E₃E_(ii)E₄ AlkL E₅ E_(b) 1086 E_(1b)E₂E₃E_(ii)E₄ AlkL E₅ E_(b) 1087 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkL E₅ E_(b) 1088 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkL E₅ E_(b) 1089 E_(1a)E₂E_(iii) AlkL E₅ E_(b) 1090 E_(1b)E₂E_(iii) AlkL E₅ E_(b) 1091 E_(1a)E₂E₃E_(iii) AlkL E₅ E_(b) 1092 E_(1b)E₂E₃E_(iii) AlkL E₅ E_(b) 1093 E_(1a)E₂E_(iii)E₄ AlkL E₅ E_(b) 1094 E_(1b)E₂E_(iii)E₄ AlkL E₅ E_(b) 1095 E_(1a)E₂E₃E_(iii)E₄ AlkL E₅ E_(b) 1096 E_(1b)E₂E₃E_(iii)E₄ AlkL E₅ E_(b) 1097 E_(1a)E₂E_(iv) AlkL E₅ E_(b) 1098 E_(1b)E₂E_(iv) AlkL E₅ E_(b) 1099 E_(1a)E₂E₃E_(iv) AlkL E₅ E_(b) 1100 E_(1b)E₂E₃E_(iv) AlkL E₅ E_(b) 1101 E_(1a)E₂E_(iv)E₄ AlkL E₅ E_(b) 1102 E_(1b)E₂E_(iv)E₄ AlkL E₅ E_(b) 1103 E_(1a)E₂E₃E_(iv)E₄ AlkL E₅ E_(b) 1104 E_(1b)E₂E₃E_(iv)E₄ AlkL E₅ E_(b) 1105 E_(1a)E₂ AlkL E₄*E₅ E_(b) 1106 E_(1b)E₂ AlkL E₄*E₅ E_(b) 1107 E_(1a)E₂E₃ AlkL E₄*E₅ E_(b) 1108 E_(1b)E₂E₃ AlkL E₄*E₅ E_(b) 1109 E_(1a)E₂E_(i) AlkL E₄*E₅ E_(b) 1110 E_(1b)E₂E_(i) AlkL E₄*E₅ E_(b) 1111 E_(1a)E₂E_(ii) AlkL E₄*E₅ E_(b) 1112 E_(1b)E₂E_(ii) AlkL E₄*E₅ E_(b) 1113 E_(1a)E₂E_(ii)E_(iib) AlkL E₄*E₅ E_(b) 1114 E_(1b)E₂E_(ii)E_(iib) AlkL E₄*E₅ E_(b) 1115 E_(1a)E₂E₃E_(i) AlkL E₄*E₅ E_(b) 1116 E_(1b)E₂E₃E_(i) AlkL E₄*E₅ E_(b) 1117 E_(1a)E₂E₃E_(ii) AlkL E₄*E₅ E_(b) 1118 E_(1b)E₂E₃E_(ii) AlkL E₄*E₅ E_(b) 1119 E_(1a)E₂E₃E_(ii)E_(iib) AlkL E₄*E₅ E_(b) 1120 E_(1b)E₂E₃E_(ii)E_(iib) AlkL E₄*E₅ E_(b) 1121 E_(1a)E₂E₄ AlkL E₄*E₅ E_(b) 1122 E_(1b)E₂E₄ AlkL E₄*E₅ E_(b) 1123 E_(1a)E₂E₃E₄ AlkL E₄*E₅ E_(b) 1124 E_(1b)E₂E₃E₄ AlkL E₄*E₅ E_(b) 1125 E_(1a)E₂E_(i)E₄ AlkL E₄*E₅ E_(b) 1126 E_(1b)E₂E_(i)E₄ AlkL E₄*E₅ E_(b) 1127 E_(1a)E₂E_(ii)E₄ AlkL E₄*E₅ E_(b) 1128 E_(1b)E₂E_(ii)E₄ AlkL E₄*E₅ E_(b) 1129 E_(1a)E₂E_(ii)E_(iib)E₄ AlkL E₄*E₅ E_(b) 1130 E_(1b)E₂E_(ii)E_(iib)E₄ AlkL E₄*E₅ E_(b) 1131 E_(1a)E₂E₃E_(i)E₄ AlkL E₄*E₅ E_(b) 1132 E_(1b)E₂E₃E_(i)E₄ AlkL E₄*E₅ E_(b) 1133 E_(1a)E₂E₃E_(ii)E₄ AlkL E₄*E₅ E_(b) 1134 E_(1b)E₂E₃E_(ii)E₄ AlkL E₄*E₅ E_(b) 1135 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkL E₄*E₅ E_(b) 1136 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkL E₄*E₅ E_(b) 1137 E_(1a)E₂E_(iii) AlkL E₄*E₅ E_(b) 1138 E_(1b)E₂E_(iii) AlkL E₄*E₅ E_(b) 1139 E_(1a)E₂E₃E_(iii) AlkL E₄*E₅ E_(b) 1140 E_(1b)E₂E₃E_(iii) AlkL E₄*E₅ E_(b) 1141 E_(1a)E₂E_(iii)E₄ AlkL E₄*E₅ E_(b) 1142 E_(1b)E₂E_(iii)E₄ AlkL E₄*E₅ E_(b) 1143 E_(1a)E₂E₃E_(iii)E₄ AlkL E₄*E₅ E_(b) 1144 E_(1b)E₂E₃E_(iii)E₄ AlkL E₄*E₅ E_(b) 1145 E_(1a)E₂E_(iv) AlkL E₄*E₅ E_(b) 1146 E_(1b)E₂E_(iv) AlkL E₄*E₅ E_(b) 1147 E_(1a)E₂E₃E_(iv) AlkL E₄*E₅ E_(b) 1148 E_(1b)E₂E₃E_(iv) AlkL E₄*E₅ E_(b) 1149 E_(1a)E₂E_(iv)E₄ AlkL E₄*E₅ E_(b) 1150 E_(1b)E₂E_(iv)E₄ AlkL E₄*E₅ E_(b) 1151 E_(1a)E₂E₃E_(iv)E₄ AlkL E₄*E₅ E_(b) 1152 E_(1b)E₂E₃E_(iv)E₄ AlkL E₄*E₅ E_(b) 1153 E_(1a)E₂ E_(d) 1154 E_(1b)E₂ E_(d) 1155 E_(1a)E₂E₃ E_(d) 1156 E_(1b)E₂E₃ E_(d) 1157 E_(1a)E₂E_(i) E_(d) 1158 E_(1b)E₂E_(i) E_(d) 1159 E_(1a)E₂E_(ii) E_(d) 1160 E_(1b)E₂E_(ii) E_(d) 1161 E_(1a)E₂E_(ii)E_(iib) E_(d) 1162 E_(1b)E₂E_(ii)E_(iib) E_(d) 1163 E_(1a)E₂E₃E_(i) E_(d) 1164 E_(1b)E₂E₃E_(i) E_(d) 1165 E_(1a)E₂E₃E_(ii) E_(d) 1166 E_(1b)E₂E₃E_(ii) E_(d) 1167 E_(1a)E₂E₃E_(ii)E_(iib) E_(d) 1168 E_(1b)E₂E₃E_(ii)E_(iib) E_(d) 1169 E_(1a)E₂E₄ E_(d) 1170 E_(1b)E₂E₄ E_(d) 1171 E_(1a)E₂E₃E₄ E_(d) 1172 E_(1b)E₂E₃E₄ E_(d) 1173 E_(1a)E₂E_(i)E₄ E_(d) 1174 E_(1b)E₂E_(i)E₄ E_(d) 1175 E_(1a)E₂E_(ii)E₄ E_(d) 1176 E_(1b)E₂E_(ii)E₄ E_(d) 1177 E_(1a)E₂E_(ii)E_(iib)E₄ E_(d) 1178 E_(1b)E₂E_(ii)E_(iib)E₄ E_(d) 1179 E_(1a)E₂E₃E_(i)E₄ E_(d) 1180 E_(1b)E₂E₃E_(i)E₄ E_(d) 1181 E_(1a)E₂E₃E_(ii)E₄ E_(d) 1182 E_(1b)E₂E₃E_(ii)E₄ E_(d) 1183 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E_(d) 1184 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E_(d) 1185 E_(1a)E₂E_(iii) E_(d) 1186 E_(1b)E₂E_(iii) E_(d) 1187 E_(1a)E₂E₃E_(iii) E_(d) 1188 E_(1b)E₂E₃E_(iii) E_(d) 1189 E_(1a)E₂E_(iii)E₄ E_(d) 1190 E_(1b)E₂E_(iii)E₄ E_(d) 1191 E_(1a)E₂E₃E_(iii)E₄ E_(d) 1192 E_(1b)E₂E₃E_(iii)E₄ E_(d) 1193 E_(1a)E₂E_(iv) E_(d) 1194 E_(1b)E₂E_(iv) E_(d) 1195 E_(1a)E₂E₃E_(iv) E_(d) 1196 E_(1b)E₂E₃E_(iv) E_(d) 1197 E_(1a)E₂E_(iv)E₄ E_(d) 1198 E_(1b)E₂E_(iv)E₄ E_(d) 1199 E_(1a)E₂E₃E_(iv)E₄ E_(d) 1200 E_(1b)E₂E₃E_(iv)E₄ E_(d) 1201 E_(1a)E₂ E₄* E_(d) 1202 E_(1b)E₂ E₄* E_(d) 1203 E_(1a)E₂E₃ E₄* E_(d) 1204 E_(1b)E₂E₃ E₄* E_(d) 1205 E_(1a)E₂E_(i) E₄* E_(d) 1206 E_(1b)E₂E_(i) E₄* E_(d) 1207 E_(1a)E₂E_(ii) E₄* E_(d) 1208 E_(1b)E₂E_(ii) E₄* E_(d) 1209 E_(1a)E₂E_(ii)E_(iib) E₄* E_(d) 1210 E_(1b)E₂E_(ii)E_(iib) E₄* E_(d) 1211 E_(1a)E₂E₃E_(i) E₄* E_(d) 1212 E_(1b)E₂E₃E_(i) E₄* E_(d) 1213 E_(1a)E₂E₃E_(ii) E₄* E_(d) 1214 E_(1b)E₂E₃E_(ii) E₄* E_(d) 1215 E_(1a)E₂E₃E_(ii)E_(iib) E₄* E_(d) 1216 E_(1b)E₂E₃E_(ii)E_(iib) E₄* E_(d) 1217 E_(1a)E₂E₄ E₄* E_(d) 1218 E_(1b)E₂E₄ E₄* E_(d) 1219 E_(1a)E₂E₃E₄ E₄* E_(d) 1220 E_(1b)E₂E₃E₄ E₄* E_(d) 1221 E_(1a)E₂E_(i)E₄ E₄* E_(d) 1222 E_(1b)E₂E_(i)E₄ E₄* E_(d) 1223 E_(1a)E₂E_(ii)E₄ E₄* E_(d) 1224 E_(1b)E₂E_(ii)E₄ E₄* E_(d) 1225 E_(1a)E₂E_(ii)E_(iib)E₄ E₄* E_(d) 1226 E_(1b)E₂E_(ii)E_(iib)E₄ E₄* E_(d) 1227 E_(1a)E₂E₃E_(i)E₄ E₄* E_(d) 1228 E_(1b)E₂E₃E_(i)E₄ E₄* E_(d) 1229 E_(1a)E₂E₃E_(ii)E₄ E₄* E_(d) 1230 E_(1b)E₂E₃E_(ii)E₄ E₄* E_(d) 1231 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E₄* E_(d) 1232 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E₄* E_(d) 1233 E_(1a)E₂E_(iii) E₄* E_(d) 1234 E_(1b)E₂E_(iii) E₄* E_(d) 1235 E_(1a)E₂E₃E_(iii) E₄* E_(d) 1236 E_(1b)E₂E₃E_(iii) E₄* E_(d) 1237 E_(1a)E₂E_(iii)E₄ E₄* E_(d) 1238 E_(1b)E₂E_(iii)E₄ E₄* E_(d) 1239 E_(1a)E₂E₃E_(iii)E₄ E₄* E_(d) 1240 E_(1b)E₂E₃E_(iii)E₄ E₄* E_(d) 1241 E_(1a)E₂E_(iv) E₄* E_(d) 1242 E_(1b)E₂E_(iv) E₄* E_(d) 1243 E_(1a)E₂E₃E_(iv) E₄* E_(d) 1244 E_(1b)E₂E₃E_(iv) E₄* E_(d) 1245 E_(1a)E₂E_(iv)E₄ E₄* E_(d) 1246 E_(1b)E₂E_(iv)E₄ E₄* E_(d) 1247 E_(1a)E₂E₃E_(iv)E₄ E₄* E_(d) 1248 E_(1b)E₂E₃E_(iv)E₄ E₄* E_(d) 1249 E_(1a)E₂ E₅ E_(d) 1250 E_(1b)E₂ E₅ E_(d) 1251 E_(1a)E₂E₃ E₅ E_(d) 1252 E_(1b)E₂E₃ E₅ E_(d) 1253 E_(1a)E₂E_(i) E₅ E_(d) 1254 E_(1b)E₂E_(i) E₅ E_(d) 1255 E_(1a)E₂E_(ii) E₅ E_(d) 1256 E_(1b)E₂E_(ii) E₅ E_(d) 1257 E_(1a)E₂E_(ii)E_(iib) E₅ E_(d) 1258 E_(1b)E₂E_(ii)E_(iib) E₅ E_(d) 1259 E_(1a)E₂E₃E_(i) E₅ E_(d) 1260 E_(1b)E₂E₃E_(i) E₅ E_(d) 1261 E_(1a)E₂E₃E_(ii) E₅ E_(d) 1262 E_(1b)E₂E₃E_(ii) E₅ E_(d) 1263 E_(1a)E₂E₃E_(ii)E_(iib) E₅ E_(d) 1264 E_(1b)E₂E₃E_(ii)E_(iib) E₅ E_(d) 1265 E_(1a)E₂E₄ E₅ E_(d) 1266 E_(1b)E₂E₄ E₅ E_(d) 1267 E_(1a)E₂E₃E₄ E₅ E_(d) 1268 E_(1b)E₂E₃E₄ E₅ E_(d) 1269 E_(1a)E₂E_(i)E₄ E₅ E_(d) 1270 E_(1b)E₂E_(i)E₄ E₅ E_(d) 1271 E_(1a)E₂E_(ii)E₄ E₅ E_(d) 1272 E_(1b)E₂E_(ii)E₄ E₅ E_(d) 1273 E_(1a)E₂E_(ii)E_(iib)E₄ E₅ E_(d) 1274 E_(1b)E₂E_(ii)E_(iib)E₄ E₅ E_(d) 1275 E_(1a)E₂E₃E_(i)E₄ E₅ E_(d) 1276 E_(1b)E₂E₃E_(i)E₄ E₅ E_(d) 1277 E_(1a)E₂E₃E_(ii)E₄ E₅ E_(d) 1278 E_(1b)E₂E₃E_(ii)E₄ E₅ E_(d) 1279 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E₅ E_(d) 1280 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E₅ E_(d) 1281 E_(1a)E₂E_(iii) E₅ E_(d) 1282 E_(1b)E₂E_(iii) E₅ E_(d) 1283 E_(1a)E₂E₃E_(iii) E₅ E_(d) 1284 E_(1b)E₂E₃E_(iii) E₅ E_(d) 1285 E_(1a)E₂E_(iii)E₄ E₅ E_(d) 1286 E_(1b)E₂E_(iii)E₄ E₅ E_(d) 1287 E_(1a)E₂E₃E_(iii)E₄ E₅ E_(d) 1288 E_(1b)E₂E₃E_(iii)E₄ E₅ E_(d) 1289 E_(1a)E₂E_(iv) E₅ E_(d) 1290 E_(1b)E₂E_(iv) E₅ E_(d) 1291 E_(1a)E₂E₃E_(iv) E₅ E_(d) 1292 E_(1b)E₂E₃E_(iv) E₅ E_(d) 1293 E_(1a)E₂E_(iv)E₄ E₅ E_(d) 1294 E_(1b)E₂E_(iv)E₄ E₅ E_(d) 1295 E_(1a)E₂E₃E_(iv)E₄ E₅ E_(d) 1296 E_(1b)E₂E₃E_(iv)E₄ E₅ E_(d) 1297 E_(1a)E₂ E₄*E₅ E_(d) 1298 E_(1b)E₂ E₄*E₅ E_(d) 1299 E_(1a)E₂E₃ E₄*E₅ E_(d) 1300 E_(1b)E₂E₃ E₄*E₅ E_(d) 1301 E_(1a)E₂E_(i) E₄*E₅ E_(d) 1302 E_(1b)E₂E_(i) E₄*E₅ E_(d) 1303 E_(1a)E₂E_(ii) E₄*E₅ E_(d) 1304 E_(1b)E₂E_(ii) E₄*E₅ E_(d) 1305 E_(1a)E₂E_(ii)E_(iib) E₄*E₅ E_(d) 1306 E_(1b)E₂E_(ii)E_(iib) E₄*E₅ E_(d) 1307 E_(1a)E₂E₃E_(i) E₄*E₅ E_(d) 1308 E_(1b)E₂E₃E_(i) E₄*E₅ E_(d) 1309 E_(1a)E₂E₃E_(ii) E₄*E₅ E_(d) 1310 E_(1b)E₂E₃E_(ii) E₄*E₅ E_(d) 1311 E_(1a)E₂E₃E_(ii)E_(iib) E₄*E₅ E_(d) 1312 E_(1b)E₂E₃E_(ii)E_(iib) E₄*E₅ E_(d) 1313 E_(1a)E₂E₄ E₄*E₅ E_(d) 1314 E_(1b)E₂E₄ E₄*E₅ E_(d) 1315 E_(1a)E₂E₃E₄ E₄*E₅ E_(d) 1316 E_(1b)E₂E₃E₄ E₄*E₅ E_(d) 1317 E_(1a)E₂E_(i)E₄ E₄*E₅ E_(d) 1318 E_(1b)E₂E_(i)E₄ E₄*E₅ E_(d) 1319 E_(1a)E₂E_(ii)E₄ E₄*E₅ E_(d) 1320 E_(1b)E₂E_(ii)E₄ E₄*E₅ E_(d) 1321 E_(1a)E₂E_(ii)E_(iib)E₄ E₄*E₅ E_(d) 1322 E_(1b)E₂E_(ii)E_(iib)E₄ E₄*E₅ E_(d) 1323 E_(1a)E₂E₃E_(i)E₄ E₄*E₅ E_(d) 1324 E_(1b)E₂E₃E_(i)E₄ E₄*E₅ E_(d) 1325 E_(1a)E₂E₃E_(ii)E₄ E₄*E₅ E_(d) 1326 E_(1b)E₂E₃E_(ii)E₄ E₄*E₅ E_(d) 1327 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E₄*E₅ E_(d) 1328 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E₄*E₅ E_(d) 1329 E_(1a)E₂E_(iii) E₄*E₅ E_(d) 1330 E_(1b)E₂E_(iii) E₄*E₅ E_(d) 1331 E_(1a)E₂E₃E_(iii) E₄*E₅ E_(d) 1332 E_(1b)E₂E₃E_(iii) E₄*E₅ E_(d) 1333 E_(1a)E₂E_(iii)E₄ E₄*E₅ E_(d) 1334 E_(1b)E₂E_(iii)E₄ E₄*E₅ E_(d) 1335 E_(1a)E₂E₃E_(iii)E₄ E₄*E₅ E_(d) 1336 E_(1b)E₂E₃E_(iii)E₄ E₄*E₅ E_(d) 1337 E_(1a)E₂E_(iv) E₄*E₅ E_(d) 1338 E_(1b)E₂E_(iv) E₄*E₅ E_(d) 1339 E_(1a)E₂E₃E_(iv) E₄*E₅ E_(d) 1340 E_(1b)E₂E₃E_(iv) E₄*E₅ E_(d) 1341 E_(1a)E₂E_(iv)E₄ E₄*E₅ E_(d) 1342 E_(1b)E₂E_(iv)E₄ E₄*E₅ E_(d) 1343 E_(1a)E₂E₃E_(iv)E₄ E₄*E₅ E_(d) 1344 E_(1b)E₂E₃E_(iv)E₄ E₄*E₅ E_(d) 1345 E_(1a)E₂ AlkL E_(d) 1346 E_(1b)E₂ AlkL E_(d) 1347 E_(1a)E₂E₃ AlkL E_(d) 1348 E_(1b)E₂E₃ AlkL E_(d) 1349 E_(1a)E₂E_(i) AlkL E_(d) 1350 E_(1b)E₂E_(i) AlkL E_(d) 1351 E_(1a)E₂E_(ii) AlkL E_(d) 1352 E_(1b)E₂E_(ii) AlkL E_(d) 1353 E_(1a)E₂E_(ii)E_(iib) AlkL E_(d) 1354 E_(1b)E₂E_(ii)E_(iib) AlkL E_(d) 1355 E_(1a)E₂E₃E_(i) AlkL E_(d) 1356 E_(1b)E₂E₃E_(i) AlkL E_(d) 1357 E_(1a)E₂E₃E_(ii) AlkL E_(d) 1358 E_(1b)E₂E₃E_(ii) AlkL E_(d) 1359 E_(1a)E₂E₃E_(ii)E_(iib) AlkL E_(d) 1360 E_(1b)E₂E₃E_(ii)E_(iib) AlkL E_(d) 1361 E_(1a)E₂E₄ AlkL E_(d) 1362 E_(1b)E₂E₄ AlkL E_(d) 1363 E_(1a)E₂E₃E₄ AlkL E_(d) 1364 E_(1b)E₂E₃E₄ AlkL E_(d) 1365 E_(1a)E₂E_(i)E₄ AlkL E_(d) 1366 E_(1b)E₂E_(i)E₄ AlkL E_(d) 1367 E_(1a)E₂E_(ii)E₄ AlkL E_(d) 1368 E_(1b)E₂E_(ii)E₄ AlkL E_(d) 1369 E_(1a)E₂E_(ii)E_(iib)E₄ AlkL E_(d) 1370 E_(1b)E₂E_(ii)E_(iib)E₄ AlkL E_(d) 1371 E_(1a)E₂E₃E_(i)E₄ AlkL E_(d) 1372 E_(1b)E₂E₃E_(i)E₄ AlkL E_(d) 1373 E_(1a)E₂E₃E_(ii)E₄ AlkL E_(d) 1374 E_(1b)E₂E₃E_(ii)E₄ AlkL E_(d) 1375 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkL E_(d) 1376 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkL E_(d) 1377 E_(1a)E₂E_(iii) AlkL E_(d) 1378 E_(1b)E₂E_(iii) AlkL E_(d) 1379 E_(1a)E₂E₃E_(iii) AlkL E_(d) 1380 E_(1b)E₂E₃E_(iii) AlkL E_(d) 1381 E_(1a)E₂E_(iii)E₄ AlkL E_(d) 1382 E_(1b)E₂E_(iii)E₄ AlkL E_(d) 1383 E_(1a)E₂E₃E_(iii)E₄ AlkL E_(d) 1384 E_(1b)E₂E₃E_(iii)E₄ AlkL E_(d) 1385 E_(1a)E₂E_(iv) AlkL E_(d) 1386 E_(1b)E₂E_(iv) AlkL E_(d) 1387 E_(1a)E₂E₃E_(iv) AlkL E_(d) 1388 E_(1b)E₂E₃E_(iv) AlkL E_(d) 1389 E_(1a)E₂E_(iv)E₄ AlkL E_(d) 1390 E_(1b)E₂E_(iv)E₄ AlkL E_(d) 1391 E_(1a)E₂E₃E_(iv)E₄ AlkL E_(d) 1392 E_(1b)E₂E₃E_(iv)E₄ AlkL E_(d) 1393 E_(1a)E₂ AlkL E₄* E_(d) 1394 E_(1b)E₂ AlkL E₄* E_(d) 1395 E_(1a)E₂E₃ AlkL E₄* E_(d) 1396 E_(1b)E₂E₃ AlkL E₄* E_(d) 1397 E_(1a)E₂E_(i) AlkL E₄* E_(d) 1398 E_(1b)E₂E_(i) AlkL E₄* E_(d) 1399 E_(1a)E₂E_(ii) AlkL E₄* E_(d) 1400 E_(1b)E₂E_(ii) AlkL E₄* E_(d) 1401 E_(1a)E₂E_(ii)E_(iib) AlkL E₄* E_(d) 1402 E_(1b)E₂E_(ii)E_(iib) AlkL E₄* E_(d) 1403 E_(1a)E₂E₃E_(i) AlkL E₄* E_(d) 1404 E_(1b)E₂E₃E_(i) AlkL E₄* E_(d) 1405 E_(1a)E₂E₃E_(ii) AlkL E₄* E_(d) 1406 E_(1b)E₂E₃E_(ii) AlkL E₄* E_(d) 1407 E_(1a)E₂E₃E_(ii)E_(iib) AlkL E₄* E_(d) 1408 E_(1b)E₂E₃E_(ii)E_(iib) AlkL E₄* E_(d) 1409 E_(1a)E₂E₄ AlkL E₄* E_(d) 1410 E_(1b)E₂E₄ AlkL E₄* E_(d) 1411 E_(1a)E₂E₃E₄ AlkL E₄* E_(d) 1412 E_(1b)E₂E₃E₄ AlkL E₄* E_(d) 1413 E_(1a)E₂E_(i)E₄ AlkL E₄* E_(d) 1414 E_(1b)E₂E_(i)E₄ AlkL E₄* E_(d) 1415 E_(1a)E₂E_(ii)E₄ AlkL E₄* E_(d) 1416 E_(1b)E₂E_(ii)E₄ AlkL E₄* E_(d) 1417 E_(1a)E₂E_(ii)E_(iib)E₄ AlkL E₄* E_(d) 1418 E_(1b)E₂E_(ii)E_(iib)E₄ AlkL E₄* E_(d) 1419 E_(1a)E₂E₃E_(i)E₄ AlkL E₄* E_(d) 1420 E_(1b)E₂E₃E_(i)E₄ AlkL E₄* E_(d) 1421 E_(1a)E₂E₃E_(ii)E₄ AlkL E₄* E_(d) 1422 E_(1b)E₂E₃E_(ii)E₄ AlkL E₄* E_(d) 1423 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkL E₄* E_(d) 1424 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkL E₄* E_(d) 1425 E_(1a)E₂E_(iii) AlkL E₄* E_(d) 1426 E_(1b)E₂E_(iii) AlkL E₄* E_(d) 1427 E_(1a)E₂E₃E_(iii) AlkL E₄* E_(d) 1428 E_(1b)E₂E₃E_(iii) AlkL E₄* E_(d) 1429 E_(1a)E₂E_(iii)E₄ AlkL E₄* E_(d) 1430 E_(1b)E₂E_(iii)E₄ AlkL E₄* E_(d) 1431 E_(1a)E₂E₃E_(iii)E₄ AlkL E₄* E_(d) 1432 E_(1b)E₂E₃E_(iii)E₄ AlkL E₄* E_(d) 1433 E_(1a)E₂E_(iv) AlkL E₄* E_(d) 1434 E_(1b)E₂E_(iv) AlkL E₄* E_(d) 1435 E_(1a)E₂E₃E_(iv) AlkL E₄* E_(d) 1436 E_(1b)E₂E₃E_(iv) AlkL E₄* E_(d) 1437 E_(1a)E₂E_(iv)E₄ AlkL E₄* E_(d) 1438 E_(1b)E₂E_(iv)E₄ AlkL E₄* E_(d) 1439 E_(1a)E₂E₃E_(iv)E₄ AlkL E₄* E_(d) 1440 E_(1b)E₂E₃E_(iv)E₄ AlkL E₄* E_(d) 1441 E_(1a)E₂ AlkL E₅ E_(d) 1442 E_(1b)E₂ AlkL E₅ E_(d) 1443 E_(1a)E₂E₃ AlkL E₅ E_(d) 1444 E_(1b)E₂E₃ AlkL E₅ E_(d) 1445 E_(1a)E₂E_(i) AlkL E₅ E_(d) 1446 E_(1b)E₂E_(i) AlkL E₅ E_(d) 1447 E_(1a)E₂E_(ii) AlkL E₅ E_(d) 1448 E_(1b)E₂E_(ii) AlkL E₅ E_(d) 1449 E_(1a)E₂E_(ii)E_(iib) AlkL E₅ E_(d) 1450 E_(1b)E₂E_(ii)E_(iib) AlkL E₅ E_(d) 1451 E_(1a)E₂E₃E_(i) AlkL E₅ E_(d) 1452 E_(1b)E₂E₃E_(i) AlkL E₅ E_(d) 1453 E_(1a)E₂E₃E_(ii) AlkL E₅ E_(d) 1454 E_(1b)E₂E₃E_(ii) AlkL E₅ E_(d) 1455 E_(1a)E₂E₃E_(ii)E_(iib) AlkL E₅ E_(d) 1456 E_(1b)E₂E₃E_(ii)E_(iib) AlkL E₅ E_(d) 1457 E_(1a)E₂E₄ AlkL E₅ E_(d) 1458 E_(1b)E₂E₄ AlkL E₅ E_(d) 1459 E_(1a)E₂E₃E₄ AlkL E₅ E_(d) 1460 E_(1b)E₂E₃E₄ AlkL E₅ E_(d) 1461 E_(1a)E₂E_(i)E₄ AlkL E₅ E_(d) 1462 E_(1b)E₂E_(i)E₄ AlkL E₅ E_(d) 1463 E_(1a)E₂E_(ii)E₄ AlkL E₅ E_(d) 1464 E_(1b)E₂E_(ii)E₄ AlkL E₅ E_(d) 1465 E_(1a)E₂E_(ii)E_(iib)E₄ AlkL E₅ E_(d) 1466 E_(1b)E₂E_(ii)E_(iib)E₄ AlkL E₅ E_(d) 1467 E_(1a)E₂E₃E_(i)E₄ AlkL E₅ E_(d) 1468 E_(1b)E₂E₃E_(i)E₄ AlkL E₅ E_(d) 1469 E_(1a)E₂E₃E_(ii)E₄ AlkL E₅ E_(d) 1470 E_(1b)E₂E₃E_(ii)E₄ AlkL E₅ E_(d) 1471 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkL E₅ E_(d) 1472 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkL E₅ E_(d) 1473 E_(1a)E₂E_(iii) AlkL E₅ E_(d) 1474 E_(1b)E₂E_(iii) AlkL E₅ E_(d) 1475 E_(1a)E₂E₃E_(iii) AlkL E₅ E_(d) 1476 E_(1b)E₂E₃E_(iii) AlkL E₅ E_(d) 1477 E_(1a)E₂E_(iii)E₄ AlkL E₅ E_(d) 1478 E_(1b)E₂E_(iii)E₄ AlkL E₅ E_(d) 1479 E_(1a)E₂E₃E_(iii)E₄ AlkL E₅ E_(d) 1480 E_(1b)E₂E₃E_(iii)E₄ AlkL E₅ E_(d) 1481 E_(1a)E₂E_(iv) AlkL E₅ E_(d) 1482 E_(1b)E₂E_(iv) AlkL E₅ E_(d) 1483 E_(1a)E₂E₃E_(iv) AlkL E₅ E_(d) 1484 E_(1b)E₂E₃E_(iv) AlkL E₅ E_(d) 1485 E_(1a)E₂E_(iv)E₄ AlkL E₅ E_(d) 1486 E_(1b)E₂E_(iv)E₄ AlkL E₅ E_(d) 1487 E_(1a)E₂E₃E_(iv)E₄ AlkL E₅ E_(d) 1488 E_(1b)E₂E₃E_(iv)E₄ AlkL E₅ E_(d) 1489 E_(1a)E₂ AlkL E₄*E₅ E_(d) 1490 E_(1b)E₂ AlkL E₄*E₅ E_(d) 1491 E_(1a)E₂E₃ AlkL E₄*E₅ E_(d) 1492 E_(1b)E₂E₃ AlkL E₄*E₅ E_(d) 1493 E_(1a)E₂E_(i) AlkL E₄*E₅ E_(d) 1494 E_(1b)E₂E_(i) AlkL E₄*E₅ E_(d) 1495 E_(1a)E₂E_(ii) AlkL E₄*E₅ E_(d) 1496 E_(1b)E₂E_(ii) AlkL E₄*E₅ E_(d) 1497 E_(1a)E₂E_(ii)E_(iib) AlkL E₄*E₅ E_(d) 1498 E_(1b)E₂E_(ii)E_(iib) AlkL E₄*E₅ E_(d) 1499 E_(1a)E₂E₃E_(i) AlkL E₄*E₅ E_(d) 1500 E_(1b)E₂E₃E_(i) AlkL E₄*E₅ E_(d) 1501 E_(1a)E₂E₃E_(ii) AlkL E₄*E₅ E_(d) 1502 E_(1b)E₂E₃E_(ii) AlkL E₄*E₅ E_(d) 1503 E_(1a)E₂E₃E_(ii)E_(iib) AlkL E₄*E₅ E_(d) 1504 E_(1b)E₂E₃E_(ii)E_(iib) AlkL E₄*E₅ E_(d) 1505 E_(1a)E₂E₄ AlkL E₄*E₅ E_(d) 1506 E_(1b)E₂E₄ AlkL E₄*E₅ E_(d) 1507 E_(1a)E₂E₃E₄ AlkL E₄*E₅ E_(d) 1508 E_(1b)E₂E₃E₄ AlkL E₄*E₅ E_(d) 1509 E_(1a)E₂E_(i)E₄ AlkL E₄*E₅ E_(d) 1510 E_(1b)E₂E_(i)E₄ AlkL E₄*E₅ E_(d) 1511 E_(1a)E₂E_(ii)E₄ AlkL E₄*E₅ E_(d) 1512 E_(1b)E₂E_(ii)E₄ AlkL E₄*E₅ E_(d) 1513 E_(1a)E₂E_(ii)E_(iib)E₄ AlkL E₄*E₅ E_(d) 1514 E_(1b)E₂E_(ii)E_(iib)E₄ AlkL E₄*E₅ E_(d) 1515 E_(1a)E₂E₃E_(i)E₄ AlkL E₄*E₅ E_(d) 1516 E_(1b)E₂E₃E_(i)E₄ AlkL E₄*E₅ E_(d) 1517 E_(1a)E₂E₃E_(ii)E₄ AlkL E₄*E₅ E_(d) 1518 E_(1b)E₂E₃E_(ii)E₄ AlkL E₄*E₅ E_(d) 1519 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkL E₄*E₅ E_(d) 1520 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkL E₄*E₅ E_(d) 1521 E_(1a)E₂E_(iii) AlkL E₄*E₅ E_(d) 1522 E_(1b)E₂E_(iii) AlkL E₄*E₅ E_(d) 1523 E_(1a)E₂E₃E_(iii) AlkL E₄*E₅ E_(d) 1524 E_(1b)E₂E₃E_(iii) AlkL E₄*E₅ E_(d) 1525 E_(1a)E₂E_(iii)E₄ AlkL E₄*E₅ E_(d) 1526 E_(1b)E₂E_(iii)E₄ AlkL E₄*E₅ E_(d) 1527 E_(1a)E₂E₃E_(iii)E₄ AlkL E₄*E₅ E_(d) 1528 E_(1b)E₂E₃E_(iii)E₄ AlkL E₄*E₅ E_(d) 1529 E_(1a)E₂E_(iv) AlkL E₄*E₅ E_(d) 1530 E_(1b)E₂E_(iv) AlkL E₄*E₅ E_(d) 1531 E_(1a)E₂E₃E_(iv) AlkL E₄*E₅ E_(d) 1532 E_(1b)E₂E₃E_(iv) AlkL E₄*E₅ E_(d) 1533 E_(1a)E₂E_(iv)E₄ AlkL E₄*E₅ E_(d) 1534 E_(1b)E₂E_(iv)E₄ AlkL E₄*E₅ E_(d) 1535 E_(1a)E₂E₃E_(iv)E₄ AlkL E₄*E₅ E_(d) 1536 E_(1b)E₂E₃E_(iv)E₄ AlkL E₄*E₅ E_(d) 1537 E_(1a)E₂ E_(e) 1538 E_(1b)E₂ E_(e) 1539 E_(1a)E₂E₃ E_(e) 1540 E_(1b)E₂E₃ E_(e) 1541 E_(1a)E₂E_(i) E_(e) 1542 E_(1b)E₂E_(i) E_(e) 1543 E_(1a)E₂E_(ii) E_(e) 1544 E_(1b)E₂E_(ii) E_(e) 1545 E_(1a)E₂E_(ii)E_(iib) E_(e) 1546 E_(1b)E₂E_(ii)E_(iib) E_(e) 1547 E_(1a)E₂E₃E_(i) E_(e) 1548 E_(1b)E₂E₃E_(i) E_(e) 1549 E_(1a)E₂E₃E_(ii) E_(e) 1550 E_(1b)E₂E₃E_(ii) E_(e) 1551 E_(1a)E₂E₃E_(ii)E_(iib) E_(e) 1552 E_(1b)E₂E₃E_(ii)E_(iib) E_(e) 1553 E_(1a)E₂E₄ E_(e) 1554 E_(1b)E₂E₄ E_(e) 1555 E_(1a)E₂E₃E₄ E_(e) 1556 E_(1b)E₂E₃E₄ E_(e) 1557 E_(1a)E₂E_(i)E₄ E_(e) 1558 E_(1b)E₂E_(i)E₄ E_(e) 1559 E_(1a)E₂E_(ii)E₄ E_(e) 1560 E_(1b)E₂E_(ii)E₄ E_(e) 1561 E_(1a)E₂E_(ii)E_(iib)E₄ E_(e) 1562 E_(1b)E₂E_(ii)E_(iib)E₄ E_(e) 1563 E_(1a)E₂E₃E_(i)E₄ E_(e) 1564 E_(1b)E₂E₃E_(i)E₄ E_(e) 1565 E_(1a)E₂E₃E_(ii)E₄ E_(e) 1566 E_(1b)E₂E₃E_(ii)E₄ E_(e) 1567 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E_(e) 1568 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E_(e) 1569 E_(1a)E₂E_(iii) E_(e) 1570 E_(1b)E₂E_(iii) E_(e) 1571 E_(1a)E₂E₃E_(iii) E_(e) 1572 E_(1b)E₂E₃E_(iii) E_(e) 1573 E_(1a)E₂E_(iii)E₄ E_(e) 1574 E_(1b)E₂E_(iii)E₄ E_(e) 1575 E_(1a)E₂E₃E_(iii)E₄ E_(e) 1576 E_(1b)E₂E₃E_(iii)E₄ E_(e) 1577 E_(1a)E₂E_(iv) E_(e) 1578 E_(1b)E₂E_(iv) E_(e) 1579 E_(1a)E₂E₃E_(iv) E_(e) 1580 E_(1b)E₂E₃E_(iv) E_(e) 1581 E_(1a)E₂E_(iv)E₄ E_(e) 1582 E_(1b)E₂E_(iv)E₄ E_(e) 1583 E_(1a)E₂E₃E_(iv)E₄ E_(e) 1584 E_(1b)E₂E₃E_(iv)E₄ E_(e) 1585 E_(1a)E₂ E₄* E_(e) 1586 E_(1b)E₂ E₄* E_(e) 1587 E_(1a)E₂E₃ E₄* E_(e) 1588 E_(1b)E₂E₃ E₄* E_(e) 1589 E_(1a)E₂E_(i) E₄* E_(e) 1590 E_(1b)E₂E_(i) E₄* E_(e) 1591 E_(1a)E₂E_(ii) E₄* E_(e) 1592 E_(1b)E₂E_(ii) E₄* E_(e) 1593 E_(1a)E₂E_(ii)E_(iib) E₄* E_(e) 1594 E_(1b)E₂E_(ii)E_(iib) E₄* E_(e) 1595 E_(1a)E₂E₃E_(i) E₄* E_(e) 1596 E_(1b)E₂E₃E_(i) E₄* E_(e) 1597 E_(1a)E₂E₃E_(ii) E₄* E_(e) 1598 E_(1b)E₂E₃E_(ii) E₄* E_(e) 1599 E_(1a)E₂E₃E_(ii)E_(iib) E₄* E_(e) 1600 E_(1b)E₂E₃E_(ii)E_(iib) E₄* E_(e) 1601 E_(1a)E₂E₄ E₄* E_(e) 1602 E_(1b)E₂E₄ E₄* E_(e) 1603 E_(1a)E₂E₃E₄ E₄* E_(e) 1604 E_(1b)E₂E₃E₄ E₄* E_(e) 1605 E_(1a)E₂E_(i)E₄ E₄* E_(e) 1606 E_(1b)E₂E_(i)E₄ E₄* E_(e) 1607 E_(1a)E₂E_(ii)E₄ E₄* E_(e) 1608 E_(1b)E₂E_(ii)E₄ E₄* E_(e) 1609 E_(1a)E₂E_(ii)E_(iib)E₄ E₄* E_(e) 1610 E_(1b)E₂E_(ii)E_(iib)E₄ E₄* E_(e) 1611 E_(1a)E₂E₃E_(i)E₄ E₄* E_(e) 1612 E_(1b)E₂E₃E_(i)E₄ E₄* E_(e) 1613 E_(1a)E₂E₃E_(ii)E₄ E₄* E_(e) 1614 E_(1b)E₂E₃E_(ii)E₄ E₄* E_(e) 1615 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E₄* E_(e) 1616 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E₄* E_(e) 1617 E_(1a)E₂E_(iii) E₄* E_(e) 1618 E_(1b)E₂E_(iii) E₄* E_(e) 1619 E_(1a)E₂E₃E_(iii) E₄* E_(e) 1620 E_(1b)E₂E₃E_(iii) E₄* E_(e) 1621 E_(1a)E₂E_(iii)E₄ E₄* E_(e) 1622 E_(1b)E₂E_(iii)E₄ E₄* E_(e) 1623 E_(1a)E₂E₃E_(iii)E₄ E₄* E_(e) 1624 E_(1b)E₂E₃E_(iii)E₄ E₄* E_(e) 1625 E_(1a)E₂E_(iv) E₄* E_(e) 1626 E_(1b)E₂E_(iv) E₄* E_(e) 1627 E_(1a)E₂E₃E_(iv) E₄* E_(e) 1628 E_(1b)E₂E₃E_(iv) E₄* E_(e) 1629 E_(1a)E₂E_(iv)E₄ E₄* E_(e) 1630 E_(1b)E₂E_(iv)E₄ E₄* E_(e) 1631 E_(1a)E₂E₃E_(iv)E₄ E₄* E_(e) 1632 E_(1b)E₂E₃E_(iv)E₄ E₄* E_(e) 1633 E_(1a)E₂ E₅ E_(e) 1634 E_(1b)E₂ E₅ E_(e) 1635 E_(1a)E₂E₃ E₅ E_(e) 1636 E_(1b)E₂E₃ E₅ E_(e) 1637 E_(1a)E₂E_(i) E₅ E_(e) 1638 E_(1b)E₂E_(i) E₅ E_(e) 1639 E_(1a)E₂E_(ii) E₅ E_(e) 1640 E_(1b)E₂E_(ii) E₅ E_(e) 1641 E_(1a)E₂E_(ii)E_(iib) E₅ E_(e) 1642 E_(1b)E₂E_(ii)E_(iib) E₅ E_(e) 1643 E_(1a)E₂E₃E_(i) E₅ E_(e) 1644 E_(1b)E₂E₃E_(i) E₅ E_(e) 1645 E_(1a)E₂E₃E_(ii) E₅ E_(e) 1646 E_(1b)E₂E₃E_(ii) E₅ E_(e) 1647 E_(1a)E₂E₃E_(ii)E_(iib) E₅ E_(e) 1648 E_(1b)E₂E₃E_(ii)E_(iib) E₅ E_(e) 1649 E_(1a)E₂E₄ E₅ E_(e) 1650 E_(1b)E₂E₄ E₅ E_(e) 1651 E_(1a)E₂E₃E₄ E₅ E_(e) 1652 E_(1b)E₂E₃E₄ E₅ E_(e) 1653 E_(1a)E₂E_(i)E₄ E₅ E_(e) 1654 E_(1b)E₂E_(i)E₄ E₅ E_(e) 1655 E_(1a)E₂E_(ii)E₄ E₅ E_(e) 1656 E_(1b)E₂E_(ii)E₄ E₅ E_(e) 1657 E_(1a)E₂E_(ii)E_(iib)E₄ E₅ E_(e) 1658 E_(1b)E₂E_(ii)E_(iib)E₄ E₅ E_(e) 1659 E_(1a)E₂E₃E_(i)E₄ E₅ E_(e) 1660 E_(1b)E₂E₃E_(i)E₄ E₅ E_(e) 1661 E_(1a)E₂E₃E_(ii)E₄ E₅ E_(e) 1662 E_(1b)E₂E₃E_(ii)E₄ E₅ E_(e) 1663 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E₅ E_(e) 1664 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E₅ E_(e) 1665 E_(1a)E₂E_(iii) E₅ E_(e) 1666 E_(1b)E₂E_(iii) E₅ E_(e) 1667 E_(1a)E₂E₃E_(iii) E₅ E_(e) 1668 E_(1b)E₂E₃E_(iii) E₅ E_(e) 1669 E_(1a)E₂E_(iii)E₄ E₅ E_(e) 1670 E_(1b)E₂E_(iii)E₄ E₅ E_(e) 1671 E_(1a)E₂E₃E_(iii)E₄ E₅ E_(e) 1672 E_(1b)E₂E₃E_(iii)E₄ E₅ E_(e) 1673 E_(1a)E₂E_(iv) E₅ E_(e) 1674 E_(1b)E₂E_(iv) E₅ E_(e) 1675 E_(1a)E₂E₃E_(iv) E₅ E_(e) 1676 E_(1b)E₂E₃E_(iv) E₅ E_(e) 1677 E_(1a)E₂E_(iv)E₄ E₅ E_(e) 1678 E_(1b)E₂E_(iv)E₄ E₅ E_(e) 1679 E_(1a)E₂E₃E_(iv)E₄ E₅ E_(e) 1680 E_(1b)E₂E₃E_(iv)E₄ E₅ E_(e) 1681 E_(1a)E₂ E₄*E₅ E_(e) 1682 E_(1b)E₂ E₄*E₅ E_(e) 1683 E_(1a)E₂E₃ E₄*E₅ E_(e) 1684 E_(1b)E₂E₃ E₄*E₅ E_(e) 1685 E_(1a)E₂E_(i) E₄*E₅ E_(e) 1686 E_(1b)E₂E_(i) E₄*E₅ E_(e) 1687 E_(1a)E₂E_(ii) E₄*E₅ E_(e) 1688 E_(1b)E₂E_(ii) E₄*E₅ E_(e) 1689 E_(1a)E₂E_(ii)E_(iib) E₄*E₅ E_(e) 1690 E_(1b)E₂E_(ii)E_(iib) E₄*E₅ E_(e) 1691 E_(1a)E₂E₃E_(i) E₄*E₅ E_(e) 1692 E_(1b)E₂E₃E_(i) E₄*E₅ E_(e) 1693 E_(1a)E₂E₃E_(ii) E₄*E₅ E_(e) 1694 E_(1b)E₂E₃E_(ii) E₄*E₅ E_(e) 1695 E_(1a)E₂E₃E_(ii)E_(iib) E₄*E₅ E_(e) 1696 E_(1b)E₂E₃E_(ii)E_(iib) E₄*E₅ E_(e) 1697 E_(1a)E₂E₄ E₄*E₅ E_(e) 1698 E_(1b)E₂E₄ E₄*E₅ E_(e) 1699 E_(1a)E₂E₃E₄ E₄*E₅ E_(e) 1700 E_(1b)E₂E₃E₄ E₄*E₅ E_(e) 1701 E_(1a)E₂E_(i)E₄ E₄*E₅ E_(e) 1702 E_(1b)E₂E_(i)E₄ E₄*E₅ E_(e) 1703 E_(1a)E₂E_(ii)E₄ E₄*E₅ E_(e) 1704 E_(1b)E₂E_(ii)E₄ E₄*E₅ E_(e) 1705 E_(1a)E₂E_(ii)E_(iib)E₄ E₄*E₅ E_(e) 1706 E_(1b)E₂E_(ii)E_(iib)E₄ E₄*E₅ E_(e) 1707 E_(1a)E₂E₃E_(i)E₄ E₄*E₅ E_(e) 1708 E_(1b)E₂E₃E_(i)E₄ E₄*E₅ E_(e) 1709 E_(1a)E₂E₃E_(ii)E₄ E₄*E₅ E_(e) 1710 E_(1b)E₂E₃E_(ii)E₄ E₄*E₅ E_(e) 1711 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E₄*E₅ E_(e) 1712 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E₄*E₅ E_(e) 1713 E_(1a)E₂E_(iii) E₄*E₅ E_(e) 1714 E_(1b)E₂E_(iii) E₄*E₅ E_(e) 1715 E_(1a)E₂E₃E_(iii) E₄*E₅ E_(e) 1716 E_(1b)E₂E₃E_(iii) E₄*E₅ E_(e) 1717 E_(1a)E₂E_(iii)E₄ E₄*E₅ E_(e) 1718 E_(1b)E₂E_(iii)E₄ E₄*E₅ E_(e) 1719 E_(1a)E₂E₃E_(iii)E₄ E₄*E₅ E_(e) 1720 E_(1b)E₂E₃E_(iii)E₄ E₄*E₅ E_(e) 1721 E_(1a)E₂E_(iv) E₄*E₅ E_(e) 1722 E_(1b)E₂E_(iv) E₄*E₅ E_(e) 1723 E_(1a)E₂E₃E_(iv) E₄*E₅ E_(e) 1724 E_(1b)E₂E₃E_(iv) E₄*E₅ E_(e) 1725 E_(1a)E₂E_(iv)E₄ E₄*E₅ E_(e) 1726 E_(1b)E₂E_(iv)E₄ E₄*E₅ E_(e) 1727 E_(1a)E₂E₃E_(iv)E₄ E₄*E₅ E_(e) 1728 E_(1b)E₂E₃E_(iv)E₄ E₄*E₅ E_(e) 1729 E_(1a)E₂ AlkL E_(e) 1730 E_(1b)E₂ AlkL E_(e) 1731 E_(1a)E₂E₃ AlkL E_(e) 1732 E_(1b)E₂E₃ AlkL E_(e) 1733 E_(1a)E₂E_(i) AlkL E_(e) 1734 E_(1b)E₂E_(i) AlkL E_(e) 1735 E_(1a)E₂E_(ii) AlkL E_(e) 1736 E_(1b)E₂E_(ii) AlkL E_(e) 1737 E_(1a)E₂E_(ii)E_(iib) AlkL E_(e) 1738 E_(1b)E₂E_(ii)E_(iib) AlkL E_(e) 1739 E_(1a)E₂E₃E_(i) AlkL E_(e) 1740 E_(1b)E₂E₃E_(i) AlkL E_(e) 1741 E_(1a)E₂E₃E_(ii) AlkL E_(e) 1742 E_(1b)E₂E₃E_(ii) AlkL E_(e) 1743 E_(1a)E₂E₃E_(ii)E_(iib) AlkL E_(e) 1744 E_(1b)E₂E₃E_(ii)E_(iib) AlkL E_(e) 1745 E_(1a)E₂E₄ AlkL E_(e) 1746 E_(1b)E₂E₄ AlkL E_(e) 1747 E_(1a)E₂E₃E₄ AlkL E_(e) 1748 E_(1b)E₂E₃E₄ AlkL E_(e) 1749 E_(1a)E₂E_(i)E₄ AlkL E_(e) 1750 E_(1b)E₂E_(i)E₄ AlkL E_(e) 1751 E_(1a)E₂E_(ii)E₄ AlkL E_(e) 1752 E_(1b)E₂E_(ii)E₄ AlkL E_(e) 1753 E_(1a)E₂E_(ii)E_(iib)E₄ AlkL E_(e) 1754 E_(1b)E₂E_(ii)E_(iib)E₄ AlkL E_(e) 1755 E_(1a)E₂E₃E_(i)E₄ AlkL E_(e) 1756 E_(1b)E₂E₃E_(i)E₄ AlkL E_(e) 1757 E_(1a)E₂E₃E_(ii)E₄ AlkL E_(e) 1758 E_(1b)E₂E₃E_(ii)E₄ AlkL E_(e) 1759 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkL E_(e) 1760 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkL E_(e) 1761 E_(1a)E₂E_(iii) AlkL E_(e) 1762 E_(1b)E₂E_(iii) AlkL E_(e) 1763 E_(1a)E₂E₃E_(iii) AlkL E_(e) 1764 E_(1b)E₂E₃E_(iii) AlkL E_(e) 1765 E_(1a)E₂E_(iii)E₄ AlkL E_(e) 1766 E_(1b)E₂E_(iii)E₄ AlkL E_(e) 1767 E_(1a)E₂E₃E_(iii)E₄ AlkL E_(e) 1768 E_(1b)E₂E₃E_(iii)E₄ AlkL E_(e) 1769 E_(1a)E₂E_(iv) AlkL E_(e) 1770 E_(1b)E₂E_(iv) AlkL E_(e) 1771 E_(1a)E₂E₃E_(iv) AlkL E_(e) 1772 E_(1b)E₂E₃E_(iv) AlkL E_(e) 1773 E_(1a)E₂E_(iv)E₄ AlkL E_(e) 1774 E_(1b)E₂E_(iv)E₄ AlkL E_(e) 1775 E_(1a)E₂E₃E_(iv)E₄ AlkL E_(e) 1776 E_(1b)E₂E₃E_(iv)E₄ AlkL E_(e) 1777 E_(1a)E₂ AlkL E₄* E_(e) 1778 E_(1b)E₂ AlkL E₄* E_(e) 1779 E_(1a)E₂E₃ AlkL E₄* E_(e) 1780 E_(1b)E₂E₃ AlkL E₄* E_(e) 1781 E_(1a)E₂E_(i) AlkL E₄* E_(e) 1782 E_(1b)E₂E_(i) AlkL E₄* E_(e) 1783 E_(1a)E₂E_(ii) AlkL E₄* E_(e) 1784 E_(1b)E₂E_(ii) AlkL E₄* E_(e) 1785 E_(1a)E₂E_(ii)E_(iib) AlkL E₄* E_(e) 1786 E_(1b)E₂E_(ii)E_(iib) AlkL E₄* E_(e) 1787 E_(1a)E₂E₃E_(i) AlkL E₄* E_(e) 1788 E_(1b)E₂E₃E_(i) AlkL E₄* E_(e) 1789 E_(1a)E₂E₃E_(ii) AlkL E₄* E_(e) 1790 E_(1b)E₂E₃E_(ii) AlkL E₄* E_(e) 1791 E_(1a)E₂E₃E_(ii)E_(iib) AlkL E₄* E_(e) 1792 E_(1b)E₂E₃E_(ii)E_(iib) AlkL E₄* E_(e) 1793 E_(1a)E₂E₄ AlkL E₄* E_(e) 1794 E_(1b)E₂E₄ AlkL E₄* E_(e) 1795 E_(1a)E₂E₃E₄ AlkL E₄* E_(e) 1796 E_(1b)E₂E₃E₄ AlkL E₄* E_(e) 1797 E_(1a)E₂E_(i)E₄ AlkL E₄* E_(e) 1798 E_(1b)E₂E_(i)E₄ AlkL E₄* E_(e) 1799 E_(1a)E₂E_(ii)E₄ AlkL E₄* E_(e) 1800 E_(1b)E₂E_(ii)E₄ AlkL E₄* E_(e) 1801 E_(1a)E₂E_(ii)E_(iib)E₄ AlkL E₄* E_(e) 1802 E_(1b)E₂E_(ii)E_(iib)E₄ AlkL E₄* E_(e) 1803 E_(1a)E₂E₃E_(i)E₄ AlkL E₄* E_(e) 1804 E_(1b)E₂E₃E_(i)E₄ AlkL E₄* E_(e) 1805 E_(1a)E₂E₃E_(ii)E₄ AlkL E₄* E_(e) 1806 E_(1b)E₂E₃E_(ii)E₄ AlkL E₄* E_(e) 1807 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkL E₄* E_(e) 1808 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkL E₄* E_(e) 1809 E_(1a)E₂E_(iii) AlkL E₄* E_(e) 1810 E_(1b)E₂E_(iii) AlkL E₄* E_(e) 1811 E_(1a)E₂E₃E_(iii) AlkL E₄* E_(e) 1812 E_(1b)E₂E₃E_(iii) AlkL E₄* E_(e) 1813 E_(1a)E₂E_(iii)E₄ AlkL E₄* E_(e) 1814 E_(1b)E₂E_(iii)E₄ AlkL E₄* E_(e) 1815 E_(1a)E₂E₃E_(iii)E₄ AlkL E₄* E_(e) 1816 E_(1b)E₂E₃E_(iii)E₄ AlkL E₄* E_(e) 1817 E_(1a)E₂E_(iv) AlkL E₄* E_(e) 1818 E_(1b)E₂E_(iv) AlkL E₄* E_(e) 1819 E_(1a)E₂E₃E_(iv) AlkL E₄* E_(e) 1820 E_(1b)E₂E₃E_(iv) AlkL E₄* E_(e) 1821 E_(1a)E₂E_(iv)E₄ AlkL E₄* E_(e) 1822 E_(1b)E₂E_(iv)E₄ AlkL E₄* E_(e) 1823 E_(1a)E₂E₃E_(iv)E₄ AlkL E₄* E_(e) 1824 E_(1b)E₂E₃E_(iv)E₄ AlkL E₄* E_(e) 1825 E_(1a)E₂ AlkL E₅ E_(e) 1826 E_(1b)E₂ AlkL E₅ E_(e) 1827 E_(1a)E₂E₃ AlkL E₅ E_(e) 1828 E_(1b)E₂E₃ AlkL E₅ E_(e) 1829 E_(1a)E₂E_(i) AlkL E₅ E_(e) 1830 E_(1b)E₂E_(i) AlkL E₅ E_(e) 1831 E_(1a)E₂E_(ii) AlkL E₅ E_(e) 1832 E_(1b)E₂E_(ii) AlkL E₅ E_(e) 1833 E_(1a)E₂E_(ii)E_(iib) AlkL E₅ E_(e) 1834 E_(1b)E₂E_(ii)E_(iib) AlkL E₅ E_(e) 1835 E_(1a)E₂E₃E_(i) AlkL E₅ E_(e) 1836 E_(1b)E₂E₃E_(i) AlkL E₅ E_(e) 1837 E_(1a)E₂E₃E_(ii) AlkL E₅ E_(e) 1838 E_(1b)E₂E₃E_(ii) AlkL E₅ E_(e) 1839 E_(1a)E₂E₃E_(ii)E_(iib) AlkL E₅ E_(e) 1840 E_(1b)E₂E₃E_(ii)E_(iib) AlkL E₅ E_(e) 1841 E_(1a)E₂E₄ AlkL E₅ E_(e) 1842 E_(1b)E₂E₄ AlkL E₅ E_(e) 1843 E_(1a)E₂E₃E₄ AlkL E₅ E_(e) 1844 E_(1b)E₂E₃E₄ AlkL E₅ E_(e) 1845 E_(1a)E₂E_(i)E₄ AlkL E₅ E_(e) 1846 E_(1b)E₂E_(i)E₄ AlkL E₅ E_(e) 1847 E_(1a)E₂E_(ii)E₄ AlkL E₅ E_(e) 1848 E_(1b)E₂E_(ii)E₄ AlkL E₅ E_(e) 1849 E_(1a)E₂E_(ii)E_(iib)E₄ AlkL E₅ E_(e) 1850 E_(1b)E₂E_(ii)E_(iib)E₄ AlkL E₅ E_(e) 1851 E_(1a)E₂E₃E_(i)E₄ AlkL E₅ E_(e) 1852 E_(1b)E₂E₃E_(i)E₄ AlkL E₅ E_(e) 1853 E_(1a)E₂E₃E_(ii)E₄ AlkL E₅ E_(e) 1854 E_(1b)E₂E₃E_(ii)E₄ AlkL E₅ E_(e) 1855 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkL E₅ E_(e) 1856 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkL E₅ E_(e) 1857 E_(1a)E₂E_(iii) AlkL E₅ E_(e) 1858 E_(1b)E₂E_(iii) AlkL E₅ E_(e) 1859 E_(1a)E₂E₃E_(iii) AlkL E₅ E_(e) 1860 E_(1b)E₂E₃E_(iii) AlkL E₅ E_(e) 1861 E_(1a)E₂E_(iii)E₄ AlkL E₅ E_(e) 1862 E_(1b)E₂E_(iii)E₄ AlkL E₅ E_(e) 1863 E_(1a)E₂E₃E_(iii)E₄ AlkL E₅ E_(e) 1864 E_(1b)E₂E₃E_(iii)E₄ AlkL E₅ E_(e) 1865 E_(1a)E₂E_(iv) AlkL E₅ E_(e) 1866 E_(1b)E₂E_(iv) AlkL E₅ E_(e) 1867 E_(1a)E₂E₃E_(iv) AlkL E₅ E_(e) 1868 E_(1b)E₂E₃E_(iv) AlkL E₅ E_(e) 1869 E_(1a)E₂E_(iv)E₄ AlkL E₅ E_(e) 1870 E_(1b)E₂E_(iv)E₄ AlkL E₅ E_(e) 1871 E_(1a)E₂E₃E_(iv)E₄ AlkL E₅ E_(e) 1872 E_(1b)E₂E₃E_(iv)E₄ AlkL E₅ E_(e) 1873 E_(1a)E₂ AlkL E₄*E₅ E_(e) 1874 E_(1b)E₂ AlkL E₄*E₅ E_(e) 1875 E_(1a)E₂E₃ AlkL E₄*E₅ E_(e) 1876 E_(1b)E₂E₃ AlkL E₄*E₅ E_(e) 1877 E_(1a)E₂E_(i) AlkL E₄*E₅ E_(e) 1878 E_(1b)E₂E_(i) AlkL E₄*E₅ E_(e) 1879 E_(1a)E₂E_(ii) AlkL E₄*E₅ E_(e) 1880 E_(1b)E₂E_(ii) AlkL E₄*E₅ E_(e) 1881 E_(1a)E₂E_(ii)E_(iib) AlkL E₄*E₅ E_(e) 1882 E_(1b)E₂E_(ii)E_(iib) AlkL E₄*E₅ E_(e) 1883 E_(1a)E₂E₃E_(i) AlkL E₄*E₅ E_(e) 1884 E_(1b)E₂E₃E_(i) AlkL E₄*E₅ E_(e) 1885 E_(1a)E₂E₃E_(ii) AlkL E₄*E₅ E_(e) 1886 E_(1b)E₂E₃E_(ii) AlkL E₄*E₅ E_(e) 1887 E_(1a)E₂E₃E_(ii)E_(iib) AlkL E₄*E₅ E_(e) 1888 E_(1b)E₂E₃E_(ii)E_(iib) AlkL E₄*E₅ E_(e) 1889 E_(1a)E₂E₄ AlkL E₄*E₅ E_(e) 1890 E_(1b)E₂E₄ AlkL E₄*E₅ E_(e) 1891 E_(1a)E₂E₃E₄ AlkL E₄*E₅ E_(e) 1892 E_(1b)E₂E₃E₄ AlkL E₄*E₅ E_(e) 1893 E_(1a)E₂E_(i)E₄ AlkL E₄*E₅ E_(e) 1894 E_(1b)E₂E_(i)E₄ AlkL E₄*E₅ E_(e) 1895 E_(1a)E₂E_(ii)E₄ AlkL E₄*E₅ E_(e) 1896 E_(1b)E₂E_(ii)E₄ AlkL E₄*E₅ E_(e) 1897 E_(1a)E₂E_(ii)E_(iib)E₄ AlkL E₄*E₅ E_(e) 1898 E_(1b)E₂E_(ii)E_(iib)E₄ AlkL E₄*E₅ E_(e) 1899 E_(1a)E₂E₃E_(i)E₄ AlkL E₄*E₅ E_(e) 1900 E_(1b)E₂E₃E_(i)E₄ AlkL E₄*E₅ E_(e) 1901 E_(1a)E₂E₃E_(ii)E₄ AlkL E₄*E₅ E_(e) 1902 E_(1b)E₂E₃E_(ii)E₄ AlkL E₄*E₅ E_(e) 1903 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkL E₄*E₅ E_(e) 1904 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkL E₄*E₅ E_(e) 1905 E_(1a)E₂E_(iii) AlkL E₄*E₅ E_(e) 1906 E_(1b)E₂E_(iii) AlkL E₄*E₅ E_(e) 1907 E_(1a)E₂E₃E_(iii) AlkL E₄*E₅ E_(e) 1908 E_(1b)E₂E₃E_(iii) AlkL E₄*E₅ E_(e) 1909 E_(1a)E₂E_(iii)E₄ AlkL E₄*E₅ E_(e) 1910 E_(1b)E₂E_(iii)E₄ AlkL E₄*E₅ E_(e) 1911 E_(1a)E₂E₃E_(iii)E₄ AlkL E₄*E₅ E_(e) 1912 E_(1b)E₂E₃E_(iii)E₄ AlkL E₄*E₅ E_(e) 1913 E_(1a)E₂E_(iv) AlkL E₄*E₅ E_(e) 1914 E_(1b)E₂E_(iv) AlkL E₄*E₅ E_(e) 1915 E_(1a)E₂E₃E_(iv) AlkL E₄*E₅ E_(e) 1916 E_(1b)E₂E₃E_(iv) AlkL E₄*E₅ E_(e) 1917 E_(1a)E₂E_(iv)E₄ AlkL E₄*E₅ E_(e) 1918 E_(1b)E₂E_(iv)E₄ AlkL E₄*E₅ E_(e) 1919 E_(1a)E₂E₃E_(iv)E₄ AlkL E₄*E₅ E_(e) 1920 E_(1b)E₂E₃E_(iv)E₄ AlkL E₄*E₅ E_(e) 1921 E_(1a)E₂ E_(f) 1922 E_(1b)E₂ E_(f) 1923 E_(1a)E₂E₃ E_(f) 1924 E_(1b)E₂E₃ E_(f) 1925 E_(1a)E₂E_(i) E_(f) 1926 E_(1b)E₂E_(i) E_(f) 1927 E_(1a)E₂E_(ii) E_(f) 1928 E_(1b)E₂E_(ii) E_(f) 1929 E_(1a)E₂E_(ii)E_(iib) E_(f) 1930 E_(1b)E₂E_(ii)E_(iib) E_(f) 1931 E_(1a)E₂E₃E_(i) E_(f) 1932 E_(1b)E₂E₃E_(i) E_(f) 1933 E_(1a)E₂E₃E_(ii) E_(f) 1934 E_(1b)E₂E₃E_(ii) E_(f) 1935 E_(1a)E₂E₃E_(ii)E_(iib) E_(f) 1936 E_(1b)E₂E₃E_(ii)E_(iib) E_(f) 1937 E_(1a)E₂E₄ E_(f) 1938 E_(1b)E₂E₄ E_(f) 1939 E_(1a)E₂E₃E₄ E_(f) 1940 E_(1b)E₂E₃E₄ E_(f) 1941 E_(1a)E₂E_(i)E₄ E_(f) 1942 E_(1b)E₂E_(i)E₄ E_(f) 1943 E_(1a)E₂E_(ii)E₄ E_(f) 1944 E_(1b)E₂E_(ii)E₄ E_(f) 1945 E_(1a)E₂E_(ii)E_(iib)E₄ E_(f) 1946 E_(1b)E₂E_(ii)E_(iib)E₄ E_(f) 1947 E_(1a)E₂E₃E_(i)E₄ E_(f) 1948 E_(1b)E₂E₃E_(i)E₄ E_(f) 1949 E_(1a)E₂E₃E_(ii)E₄ E_(f) 1950 E_(1b)E₂E₃E_(ii)E₄ E_(f) 1951 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E_(f) 1952 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E_(f) 1953 E_(1a)E₂E_(iii) E_(f) 1954 E_(1b)E₂E_(iii) E_(f) 1955 E_(1a)E₂E₃E_(iii) E_(f) 1956 E_(1b)E₂E₃E_(iii) E_(f) 1957 E_(1a)E₂E_(iii)E₄ E_(f) 1958 E_(1b)E₂E_(iii)E₄ E_(f) 1959 E_(1a)E₂E₃E_(iii)E₄ E_(f) 1960 E_(1b)E₂E₃E_(iii)E₄ E_(f) 1961 E_(1a)E₂E_(iv) E_(f) 1962 E_(1b)E₂E_(iv) E_(f) 1963 E_(1a)E₂E₃E_(iv) E_(f) 1964 E_(1b)E₂E₃E_(iv) E_(f) 1965 E_(1a)E₂E_(iv)E₄ E_(f) 1966 E_(1b)E₂E_(iv)E₄ E_(f) 1967 E_(1a)E₂E₃E_(iv)E₄ E_(f) 1968 E_(1b)E₂E₃E_(iv)E₄ E_(f) 1969 E_(1a)E₂ E₄* E_(f) 1970 E_(1b)E₂ E₄* E_(f) 1971 E_(1a)E₂E₃ E₄* E_(f) 1972 E_(1b)E₂E₃ E₄* E_(f) 1973 E_(1a)E₂E_(i) E₄* E_(f) 1974 E_(1b)E₂E_(i) E₄* E_(f) 1975 E_(1a)E₂E_(ii) E₄* E_(f) 1976 E_(1b)E₂E_(ii) E₄* E_(f) 1977 E_(1a)E₂E_(ii)E_(iib) E₄* E_(f) 1978 E_(1b)E₂E_(ii)E_(iib) E₄* E_(f) 1979 E_(1a)E₂E₃E_(i) E₄* E_(f) 1980 E_(1b)E₂E₃E_(i) E₄* E_(f) 1981 E_(1a)E₂E₃E_(ii) E₄* E_(f) 1982 E_(1b)E₂E₃E_(ii) E₄* E_(f) 1983 E_(1a)E₂E₃E_(ii)E_(iib) E₄* E_(f) 1984 E_(1b)E₂E₃E_(ii)E_(iib) E₄* E_(f) 1985 E_(1a)E₂E₄ E₄* E_(f) 1986 E_(1b)E₂E₄ E₄* E_(f) 1987 E_(1a)E₂E₃E₄ E₄* E_(f) 1988 E_(1b)E₂E₃E₄ E₄* E_(f) 1989 E_(1a)E₂E_(i)E₄ E₄* E_(f) 1990 E_(1b)E₂E_(i)E₄ E₄* E_(f) 1991 E_(1a)E₂E_(ii)E₄ E₄* E_(f) 1992 E_(1b)E₂E_(ii)E₄ E₄* E_(f) 1993 E_(1a)E₂E_(ii)E_(iib)E₄ E₄* E_(f) 1994 E_(1b)E₂E_(ii)E_(iib)E₄ E₄* E_(f) 1995 E_(1a)E₂E₃E_(i)E₄ E₄* E_(f) 1996 E_(1b)E₂E₃E_(i)E₄ E₄* E_(f) 1997 E_(1a)E₂E₃E_(ii)E₄ E₄* E_(f) 1998 E_(1b)E₂E₃E_(ii)E₄ E₄* E_(f) 1999 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E₄* E_(f) 2000 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E₄* E_(f) 2001 E_(1a)E₂E_(iii) E₄* E_(f) 2002 E_(1b)E₂E_(iii) E₄* E_(f) 2003 E_(1a)E₂E₃E_(iii) E₄* E_(f) 2004 E_(1b)E₂E₃E_(iii) E₄* E_(f) 2005 E_(1a)E₂E_(iii)E₄ E₄* E_(f) 2006 E_(1b)E₂E_(iii)E₄ E₄* E_(f) 2007 E_(1a)E₂E₃E_(iii)E₄ E₄* E_(f) 2008 E_(1b)E₂E₃E_(iii)E₄ E₄* E_(f) 2009 E_(1a)E₂E_(iv) E₄* E_(f) 2010 E_(1b)E₂E_(iv) E₄* E_(f) 2011 E_(1a)E₂E₃E_(iv) E₄* E_(f) 2012 E_(1b)E₂E₃E_(iv) E₄* E_(f) 2013 E_(1a)E₂E_(iv)E₄ E₄* E_(f) 2014 E_(1b)E₂E_(iv)E₄ E₄* E_(f) 2015 E_(1a)E₂E₃E_(iv)E₄ E₄* E_(f) 2016 E_(1b)E₂E₃E_(iv)E₄ E₄* E_(f) 2017 E_(1a)E₂ E₅ E_(f) 2018 E_(1b)E₂ E₅ E_(f) 2019 E_(1a)E₂E₃ E₅ E_(f) 2020 E_(1b)E₂E₃ E₅ E_(f) 2021 E_(1a)E₂E_(i) E₅ E_(f) 2022 E_(1b)E₂E_(i) E₅ E_(f) 2023 E_(1a)E₂E_(ii) E₅ E_(f) 2024 E_(1b)E₂E_(ii) E₅ E_(f) 2025 E_(1a)E₂E_(ii)E_(iib) E₅ E_(f) 2026 E_(1b)E₂E_(ii)E_(iib) E₅ E_(f) 2027 E_(1a)E₂E₃E_(i) E₅ E_(f) 2028 E_(1b)E₂E₃E_(i) E₅ E_(f) 2029 E_(1a)E₂E₃E_(ii) E₅ E_(f) 2030 E_(1b)E₂E₃E_(ii) E₅ E_(f) 2031 E_(1a)E₂E₃E_(ii)E_(iib) E₅ E_(f) 2032 E_(1b)E₂E₃E_(ii)E_(iib) E₅ E_(f) 2033 E_(1a)E₂E₄ E₅ E_(f) 2034 E_(1b)E₂E₄ E₅ E_(f) 2035 E_(1a)E₂E₃E₄ E₅ E_(f) 2036 E_(1b)E₂E₃E₄ E₅ E_(f) 2037 E_(1a)E₂E_(i)E₄ E₅ E_(f) 2038 E_(1b)E₂E_(i)E₄ E₅ E_(f) 2039 E_(1a)E₂E_(ii)E₄ E₅ E_(f) 2040 E_(1b)E₂E_(ii)E₄ E₅ E_(f) 2041 E_(1a)E₂E_(ii)E_(iib)E₄ E₅ E_(f) 2042 E_(1b)E₂E_(ii)E_(iib)E₄ E₅ E_(f) 2043 E_(1a)E₂E₃E_(i)E₄ E₅ E_(f) 2044 E_(1b)E₂E₃E_(i)E₄ E₅ E_(f) 2045 E_(1a)E₂E₃E_(ii)E₄ E₅ E_(f) 2046 E_(1b)E₂E₃E_(ii)E₄ E₅ E_(f) 2047 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E₅ E_(f) 2048 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E₅ E_(f) 2049 E_(1a)E₂E_(iii) E₅ E_(f) 2050 E_(1b)E₂E_(iii) E₅ E_(f) 2051 E_(1a)E₂E₃E_(iii) E₅ E_(f) 2052 E_(1b)E₂E₃E_(iii) E₅ E_(f) 2053 E_(1a)E₂E_(iii)E₄ E₅ E_(f) 2054 E_(1b)E₂E_(iii)E₄ E₅ E_(f) 2055 E_(1a)E₂E₃E_(iii)E₄ E₅ E_(f) 2056 E_(1b)E₂E₃E_(iii)E₄ E₅ E_(f) 2057 E_(1a)E₂E_(iv) E₅ E_(f) 2058 E_(1b)E₂E_(iv) E₅ E_(f) 2059 E_(1a)E₂E₃E_(iv) E₅ E_(f) 2060 E_(1b)E₂E₃E_(iv) E₅ E_(f) 2061 E_(1a)E₂E_(iv)E₄ E₅ E_(f) 2062 E_(1b)E₂E_(iv)E₄ E₅ E_(f) 2063 E_(1a)E₂E₃E_(iv)E₄ E₅ E_(f) 2064 E_(1b)E₂E₃E_(iv)E₄ E₅ E_(f) 2065 E_(1a)E₂ E₄*E₅ E_(f) 2066 E_(1b)E₂ E₄*E₅ E_(f) 2067 E_(1a)E₂E₃ E₄*E₅ E_(f) 2068 E_(1b)E₂E₃ E₄*E₅ E_(f) 2069 E_(1a)E₂E_(i) E₄*E₅ E_(f) 2070 E_(1b)E₂E_(i) E₄*E₅ E_(f) 2071 E_(1a)E₂E_(ii) E₄*E₅ E_(f) 2072 E_(1b)E₂E_(ii) E₄*E₅ E_(f) 2073 E_(1a)E₂E_(ii)E_(iib) E₄*E₅ E_(f) 2074 E_(1b)E₂E_(ii)E_(iib) E₄*E₅ E_(f) 2075 E_(1a)E₂E₃E_(i) E₄*E₅ E_(f) 2076 E_(1b)E₂E₃E_(i) E₄*E₅ E_(f) 2077 E_(1a)E₂E₃E_(ii) E₄*E₅ E_(f) 2078 E_(1b)E₂E₃E_(ii) E₄*E₅ E_(f) 2079 E_(1a)E₂E₃E_(ii)E_(iib) E₄*E₅ E_(f) 2080 E_(1b)E₂E₃E_(ii)E_(iib) E₄*E₅ E_(f) 2081 E_(1a)E₂E₄ E₄*E₅ E_(f) 2082 E_(1b)E₂E₄ E₄*E₅ E_(f) 2083 E_(1a)E₂E₃E₄ E₄*E₅ E_(f) 2084 E_(1b)E₂E₃E₄ E₄*E₅ E_(f) 2085 E_(1a)E₂E_(i)E₄ E₄*E₅ E_(f) 2086 E_(1b)E₂E_(i)E₄ E₄*E₅ E_(f) 2087 E_(1a)E₂E_(ii)E₄ E₄*E₅ E_(f) 2088 E_(1b)E₂E_(ii)E₄ E₄*E₅ E_(f) 2089 E_(1a)E₂E_(ii)E_(iib)E₄ E₄*E₅ E_(f) 2090 E_(1b)E₂E_(ii)E_(iib)E₄ E₄*E₅ E_(f) 2091 E_(1a)E₂E₃E_(i)E₄ E₄*E₅ E_(f) 2092 E_(1b)E₂E₃E_(i)E₄ E₄*E₅ E_(f) 2093 E_(1a)E₂E₃E_(ii)E₄ E₄*E₅ E_(f) 2094 E_(1b)E₂E₃E_(ii)E₄ E₄*E₅ E_(f) 2095 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E₄*E₅ E_(f) 2096 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E₄*E₅ E_(f) 2097 E_(1a)E₂E_(iii) E₄*E₅ E_(f) 2098 E_(1b)E₂E_(iii) E₄*E₅ E_(f) 2099 E_(1a)E₂E₃E_(iii) E₄*E₅ E_(f) 2100 E_(1b)E₂E₃E_(iii) E₄*E₅ E_(f) 2101 E_(1a)E₂E_(iii)E₄ E₄*E₅ E_(f) 2102 E_(1b)E₂E_(iii)E₄ E₄*E₅ E_(f) 2103 E_(1a)E₂E₃E_(iii)E₄ E₄*E₅ E_(f) 2104 E_(1b)E₂E₃E_(iii)E₄ E₄*E₅ E_(f) 2105 E_(1a)E₂E_(iv) E₄*E₅ E_(f) 2106 E_(1b)E₂E_(iv) E₄*E₅ E_(f) 2107 E_(1a)E₂E₃E_(iv) E₄*E₅ E_(f) 2108 E_(1b)E₂E₃E_(iv) E₄*E₅ E_(f) 2109 E_(1a)E₂E_(iv)E₄ E₄*E₅ E_(f) 2110 E_(1b)E₂E_(iv)E₄ E₄*E₅ E_(f) 2111 E_(1a)E₂E₃E_(iv)E₄ E₄*E₅ E_(f) 2112 E_(1b)E₂E₃E_(iv)E₄ E₄*E₅ E_(f) 2113 E_(1a)E₂ AlkL E_(f) 2114 E_(1b)E₂ AlkL E_(f) 2115 E_(1a)E₂E₃ AlkL E_(f) 2116 E_(1b)E₂E₃ AlkL E_(f) 2117 E_(1a)E₂E_(i) AlkL E_(f) 2118 E_(1b)E₂E_(i) AlkL E_(f) 2119 E_(1a)E₂E_(ii) AlkL E_(f) 2120 E_(1b)E₂E_(ii) AlkL E_(f) 2121 E_(1a)E₂E_(ii)E_(iib) AlkL E_(f) 2122 E_(1b)E₂E_(ii)E_(iib) AlkL E_(f) 2123 E_(1a)E₂E₃E_(i) AlkL E_(f) 2124 E_(1b)E₂E₃E_(i) AlkL E_(f) 2125 E_(1a)E₂E₃E_(ii) AlkL E_(f) 2126 E_(1b)E₂E₃E_(ii) AlkL E_(f) 2127 E_(1a)E₂E₃E_(ii)E_(iib) AlkL E_(f) 2128 E_(1b)E₂E₃E_(ii)E_(iib) AlkL E_(f) 2129 E_(1a)E₂E₄ AlkL E_(f) 2130 E_(1b)E₂E₄ AlkL E_(f) 2131 E_(1a)E₂E₃E₄ AlkL E_(f) 2132 E_(1b)E₂E₃E₄ AlkL E_(f) 2133 E_(1a)E₂E_(i)E₄ AlkL E_(f) 2134 E_(1b)E₂E_(i)E₄ AlkL E_(f) 2135 E_(1a)E₂E_(ii)E₄ AlkL E_(f) 2136 E_(1b)E₂E_(ii)E₄ AlkL E_(f) 2137 E_(1a)E₂E_(ii)E_(iib)E₄ AlkL E_(f) 2138 E_(1b)E₂E_(ii)E_(iib)E₄ AlkL E_(f) 2139 E_(1a)E₂E₃E_(i)E₄ AlkL E_(f) 2140 E_(1b)E₂E₃E_(i)E₄ AlkL E_(f) 2141 E_(1a)E₂E₃E_(ii)E₄ AlkL E_(f) 2142 E_(1b)E₂E₃E_(ii)E₄ AlkL E_(f) 2143 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkL E_(f) 2144 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkL E_(f) 2145 E_(1a)E₂E_(iii) AlkL E_(f) 2146 E_(1b)E₂E_(iii) AlkL E_(f) 2147 E_(1a)E₂E₃E_(iii) AlkL E_(f) 2148 E_(1b)E₂E₃E_(iii) AlkL E_(f) 2149 E_(1a)E₂E_(iii)E₄ AlkL E_(f) 2150 E_(1b)E₂E_(iii)E₄ AlkL E_(f) 2151 E_(1a)E₂E₃E_(iii)E₄ AlkL E_(f) 2152 E_(1b)E₂E₃E_(iii)E₄ AlkL E_(f) 2153 E_(1a)E₂E_(iv) AlkL E_(f) 2154 E_(1b)E₂E_(iv) AlkL E_(f) 2155 E_(1a)E₂E₃E_(iv) AlkL E_(f) 2156 E_(1b)E₂E₃E_(iv) AlkL E_(f) 2157 E_(1a)E₂E_(iv)E₄ AlkL E_(f) 2158 E_(1b)E₂E_(iv)E₄ AlkL E_(f) 2159 E_(1a)E₂E₃E_(iv)E₄ AlkL E_(f) 2160 E_(1b)E₂E₃E_(iv)E₄ AlkL E_(f) 2161 E_(1a)E₂ AlkL E₄* E_(f) 2162 E_(1b)E₂ AlkL E₄* E_(f) 2163 E_(1a)E₂E₃ AlkL E₄* E_(f) 2164 E_(1b)E₂E₃ AlkL E₄* E_(f) 2165 E_(1a)E₂E_(i) AlkL E₄* E_(f) 2166 E_(1b)E₂E_(i) AlkL E₄* E_(f) 2167 E_(1a)E₂E_(ii) AlkL E₄* E_(f) 2168 E_(1b)E₂E_(ii) AlkL E₄* E_(f) 2169 E_(1a)E₂E_(ii)E_(iib) AlkL E₄* E_(f) 2170 E_(1b)E₂E_(ii)E_(iib) AlkL E₄* E_(f) 2171 E_(1a)E₂E₃E_(i) AlkL E₄* E_(f) 2172 E_(1b)E₂E₃E_(i) AlkL E₄* E_(f) 2173 E_(1a)E₂E₃E_(ii) AlkL E₄* E_(f) 2174 E_(1b)E₂E₃E_(ii) AlkL E₄* E_(f) 2175 E_(1a)E₂E₃E_(ii)E_(iib) AlkL E₄* E_(f) 2176 E_(1b)E₂E₃E_(ii)E_(iib) AlkL E₄* E_(f) 2177 E_(1a)E₂E₄ AlkL E₄* E_(f) 2178 E_(1b)E₂E₄ AlkL E₄* E_(f) 2179 E_(1a)E₂E₃E₄ AlkL E₄* E_(f) 2180 E_(1b)E₂E₃E₄ AlkL E₄* E_(f) 2181 E_(1a)E₂E_(i)E₄ AlkL E₄* E_(f) 2182 E_(1b)E₂E_(i)E₄ AlkL E₄* E_(f) 2183 E_(1a)E₂E_(ii)E₄ AlkL E₄* E_(f) 2184 E_(1b)E₂E_(ii)E₄ AlkL E₄* E_(f) 2185 E_(1a)E₂E_(ii)E_(iib)E₄ AlkL E₄* E_(f) 2186 E_(1b)E₂E_(ii)E_(iib)E₄ AlkL E₄* E_(f) 2187 E_(1a)E₂E₃E_(i)E₄ AlkL E₄* E_(f) 2188 E_(1b)E₂E₃E_(i)E₄ AlkL E₄* E_(f) 2189 E_(1a)E₂E₃E_(ii)E₄ AlkL E₄* E_(f) 2190 E_(1b)E₂E₃E_(ii)E₄ AlkL E₄* E_(f) 2191 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkL E₄* E_(f) 2192 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkL E₄* E_(f) 2193 E_(1a)E₂E_(iii) AlkL E₄* E_(f) 2194 E_(1b)E₂E_(iii) AlkL E₄* E_(f) 2195 E_(1a)E₂E₃E_(iii) AlkL E₄* E_(f) 2196 E_(1b)E₂E₃E_(iii) AlkL E₄* E_(f) 2197 E_(1a)E₂E_(iii)E₄ AlkL E₄* E_(f) 2198 E_(1b)E₂E_(iii)E₄ AlkL E₄* E_(f) 2199 E_(1a)E₂E₃E_(iii)E₄ AlkL E₄* E_(f) 2200 E_(1b)E₂E₃E_(iii)E₄ AlkL E₄* E_(f) 2201 E_(1a)E₂E_(iv) AlkL E₄* E_(f) 2202 E_(1b)E₂E_(iv) AlkL E₄* E_(f) 2203 E_(1a)E₂E₃E_(iv) AlkL E₄* E_(f) 2204 E_(1b)E₂E₃E_(iv) AlkL E₄* E_(f) 2205 E_(1a)E₂E_(iv)E₄ AlkL E₄* E_(f) 2206 E_(1b)E₂E_(iv)E₄ AlkL E₄* E_(f) 2207 E_(1a)E₂E₃E_(iv)E₄ AlkL E₄* E_(f) 2208 E_(1b)E₂E₃E_(iv)E₄ AlkL E₄* E_(f) 2209 E_(1a)E₂ AlkL E₅ E_(f) 2210 E_(1b)E₂ AlkL E₅ E_(f) 2211 E_(1a)E₂E₃ AlkL E₅ E_(f) 2212 E_(1b)E₂E₃ AlkL E₅ E_(f) 2213 E_(1a)E₂E_(i) AlkL E₅ E_(f) 2214 E_(1b)E₂E_(i) AlkL E₅ E_(f) 2215 E_(1a)E₂E_(ii) AlkL E₅ E_(f) 2216 E_(1b)E₂E_(ii) AlkL E₅ E_(f) 2217 E_(1a)E₂E_(ii)E_(iib) AlkL E₅ E_(f) 2218 E_(1b)E₂E_(ii)E_(iib) AlkL E₅ E_(f) 2219 E_(1a)E₂E₃E_(i) AlkL E₅ E_(f) 2220 E_(1b)E₂E₃E_(i) AlkL E₅ E_(f) 2221 E_(1a)E₂E₃E_(ii) AlkL E₅ E_(f) 2222 E_(1b)E₂E₃E_(ii) AlkL E₅ E_(f) 2223 E_(1a)E₂E₃E_(ii)E_(iib) AlkL E₅ E_(f) 2224 E_(1b)E₂E₃E_(ii)E_(iib) AlkL E₅ E_(f) 2225 E_(1a)E₂E₄ AlkL E₅ E_(f) 2226 E_(1b)E₂E₄ AlkL E₅ E_(f) 2227 E_(1a)E₂E₃E₄ AlkL E₅ E_(f) 2228 E_(1b)E₂E₃E₄ AlkL E₅ E_(f) 2229 E_(1a)E₂E_(i)E₄ AlkL E₅ E_(f) 2230 E_(1b)E₂E_(i)E₄ AlkL E₅ E_(f) 2231 E_(1a)E₂E_(ii)E₄ AlkL E₅ E_(f) 2232 E_(1b)E₂E_(ii)E₄ AlkL E₅ E_(f) 2233 E_(1a)E₂E_(ii)E_(iib)E₄ AlkL E₅ E_(f) 2234 E_(1b)E₂E_(ii)E_(iib)E₄ AlkL E₅ E_(f) 2235 E_(1a)E₂E₃E_(i)E₄ AlkL E₅ E_(f) 2236 E_(1b)E₂E₃E_(i)E₄ AlkL E₅ E_(f) 2237 E_(1a)E₂E₃E_(ii)E₄ AlkL E₅ E_(f) 2238 E_(1b)E₂E₃E_(ii)E₄ AlkL E₅ E_(f) 2239 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkL E₅ E_(f) 2240 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkL E₅ E_(f) 2241 E_(1a)E₂E_(iii) AlkL E₅ E_(f) 2242 E_(1b)E₂E_(iii) AlkL E₅ E_(f) 2243 E_(1a)E₂E₃E_(iii) AlkL E₅ E_(f) 2244 E_(1b)E₂E₃E_(iii) AlkL E₅ E_(f) 2245 E_(1a)E₂E_(iii)E₄ AlkL E₅ E_(f) 2246 E_(1b)E₂E_(iii)E₄ AlkL E₅ E_(f) 2247 E_(1a)E₂E₃E_(iii)E₄ AlkL E₅ E_(f) 2248 E_(1b)E₂E₃E_(iii)E₄ AlkL E₅ E_(f) 2249 E_(1a)E₂E_(iv) AlkL E₅ E_(f) 2250 E_(1b)E₂E_(iv) AlkL E₅ E_(f) 2251 E_(1a)E₂E₃E_(iv) AlkL E₅ E_(f) 2252 E_(1b)E₂E₃E_(iv) AlkL E₅ E_(f) 2253 E_(1a)E₂E_(iv)E₄ AlkL E₅ E_(f) 2254 E_(1b)E₂E_(iv)E₄ AlkL E₅ E_(f) 2255 E_(1a)E₂E₃E_(iv)E₄ AlkL E₅ E_(f) 2256 E_(1b)E₂E₃E_(iv)E₄ AlkL E₅ E_(f) 2257 E_(1a)E₂ AlkL E₄*E₅ E_(f) 2258 E_(1b)E₂ AlkL E₄*E₅ E_(f) 2259 E_(1a)E₂E₃ AlkL E₄*E₅ E_(f) 2260 E_(1b)E₂E₃ AlkL E₄*E₅ E_(f) 2261 E_(1a)E₂E_(i) AlkL E₄*E₅ E_(f) 2262 E_(1b)E₂E_(i) AlkL E₄*E₅ E_(f) 2263 E_(1a)E₂E_(ii) AlkL E₄*E₅ E_(f) 2264 E_(1b)E₂E_(ii) AlkL E₄*E₅ E_(f) 2265 E_(1a)E₂E_(ii)E_(iib) AlkL E₄*E₅ E_(f) 2266 E_(1b)E₂E_(ii)E_(iib) AlkL E₄*E₅ E_(f) 2267 E_(1a)E₂E₃E_(i) AlkL E₄*E₅ E_(f) 2268 E_(1b)E₂E₃E_(i) AlkL E₄*E₅ E_(f) 2269 E_(1a)E₂E₃E_(ii) AlkL E₄*E₅ E_(f) 2270 E_(1b)E₂E₃E_(ii) AlkL E₄*E₅ E_(f) 2271 E_(1a)E₂E₃E_(ii)E_(iib) AlkL E₄*E₅ E_(f) 2272 E_(1b)E₂E₃E_(ii)E_(iib) AlkL E₄*E₅ E_(f) 2273 E_(1a)E₂E₄ AlkL E₄*E₅ E_(f) 2274 E_(1b)E₂E₄ AlkL E₄*E₅ E_(f) 2275 E_(1a)E₂E₃E₄ AlkL E₄*E₅ E_(f) 2276 E_(1b)E₂E₃E₄ AlkL E₄*E₅ E_(f) 2277 E_(1a)E₂E_(i)E₄ AlkL E₄*E₅ E_(f) 2278 E_(1b)E₂E_(i)E₄ AlkL E₄*E₅ E_(f) 2279 E_(1a)E₂E_(ii)E₄ AlkL E₄*E₅ E_(f) 2280 E_(1b)E₂E_(ii)E₄ AlkL E₄*E₅ E_(f) 2281 E_(1a)E₂E_(ii)E_(iib)E₄ AlkL E₄*E₅ E_(f) 2282 E_(1b)E₂E_(ii)E_(iib)E₄ AlkL E₄*E₅ E_(f) 2283 E_(1a)E₂E₃E_(i)E₄ AlkL E₄*E₅ E_(f) 2284 E_(1b)E₂E₃E_(i)E₄ AlkL E₄*E₅ E_(f) 2285 E_(1a)E₂E₃E_(ii)E₄ AlkL E₄*E₅ E_(f) 2286 E_(1b)E₂E₃E_(ii)E₄ AlkL E₄*E₅ E_(f) 2287 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkL E₄*E₅ E_(f) 2288 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkL E₄*E₅ E_(f) 2289 E_(1a)E₂E_(iii) AlkL E₄*E₅ E_(f) 2290 E_(1b)E₂E_(iii) AlkL E₄*E₅ E_(f) 2291 E_(1a)E₂E₃E_(iii) AlkL E₄*E₅ E_(f) 2292 E_(1b)E₂E₃E_(iii) AlkL E₄*E₅ E_(f) 2293 E_(1a)E₂E_(iii)E₄ AlkL E₄*E₅ E_(f) 2294 E_(1b)E₂E_(iii)E₄ AlkL E₄*E₅ E_(f) 2295 E_(1a)E₂E₃E_(iii)E₄ AlkL E₄*E₅ E_(f) 2296 E_(1b)E₂E₃E_(iii)E₄ AlkL E₄*E₅ E_(f) 2297 E_(1a)E₂E_(iv) AlkL E₄*E₅ E_(f) 2298 E_(1b)E₂E_(iv) AlkL E₄*E₅ E_(f) 2299 E_(1a)E₂E₃E_(iv) AlkL E₄*E₅ E_(f) 2300 E_(1b)E₂E₃E_(iv) AlkL E₄*E₅ E_(f) 2301 E_(1a)E₂E_(iv)E₄ AlkL E₄*E₅ E_(f) 2302 E_(1b)E₂E_(iv)E₄ AlkL E₄*E₅ E_(f) 2303 E_(1a)E₂E₃E_(iv)E₄ AlkL E₄*E₅ E_(f) 2304 E_(1b)E₂E₃E_(iv)E₄ AlkL E₄*E₅ E_(f)

Microorganisms quite especially preferred according to the invention (abbreviated as MO) are outstandingly suitable for the production of n-aminocarboxylate esters and have increased or decreased enzyme activities (abbreviated as E) described in the following table, where these can in addition advantageously be combined with an increased enzyme activity compared to the wild type of the microorganism, which is described for the 3-ketoacyl-ACP (Acyl Carrrier Protein) synthase III (EC 2.3.1.41), in particular that from plants, preferably that from plants the seeds whereof contain fatty acids with alkyl residues shorter than 14 C atoms, and particularly preferably that from plants of the genera Cuphea, Elaeis, Cocos, Umbellularia and Cinnamomum and gene products selected from AccA, AccB, AccC, AccD, AceE, AceF, Lpd, AcpP, FabA, FabB, FabD, FabF, FabG, FabH, Fabl, FabZ, PanD, PanK, UdhA, PntA or PntB. Any combinations of at least two of these enzyme activities can advantageously be increased.

In addition, moreover, it can be advantageous if the microorganism is provided with a lower enzyme activity compared to the wild type of the microorganism, which is described for the gene products selected from TdcE, PflA, PflB, PflC, PflD, PoxB, YgfG, AckA, AckB, TdcD, Pta, LdhA, AdhE, MgsA, FdnG, FdnH, FdnI, FdhF, FdoG, FdoH, FdoI, PrpC, PrpD, PrpF, PrpB, TdcD, Pdc, PorA, PorB, PorC, PorD, AlsS, IlvB, IlvM, IlvN, IlvG, IlyI, IlvH, AlsD, ButB, Thl, ThlA, ThlB, PhaA, PhaB, Crt, BdhA, BdhB, Adc, Adh, CtfB, AtoA, AtoD, LdhL, GltA, FabR, FhuA, Dld, LldA or LldP, singly or in any combination.

MO E increased E decreased 1 E_(1a)E₂ E_(v)E_(vi) 2 E_(1b)E₂ E_(v)E_(vi) 3 E_(1a)E₂E₃ E_(v)E_(vi) 4 E_(1b)E₂E₃ E_(v)E_(vi) 5 E_(1a)E₂E_(i) E_(v)E_(vi) 6 E_(1b)E₂E_(i) E_(v)E_(vi) 7 E_(1a)E₂E_(ii) E_(v)E_(vi) 8 E_(1b)E₂E_(ii) E_(v)E_(vi) 9 E_(1a)E₂E_(ii)E_(iib) E_(v)E_(vi) 10 E_(1b)E₂E_(ii)E_(iib) E_(v)E_(vi) 11 E_(1a)E₂E₃E_(i) E_(v)E_(vi) 12 E_(1b)E₂E₃E_(i) E_(v)E_(vi) 13 E_(1a)E₂E₃E_(ii) E_(v)E_(vi) 14 E_(1b)E₂E₃E_(ii) E_(v)E_(vi) 15 E_(1a)E₂E₃E_(ii)E_(iib) E_(v)E_(vi) 16 E_(1b)E₂E₃E_(ii)E_(iib) E_(v)E_(vi) 17 E_(1a)E₂E₄ E_(v)E_(vi) 18 E_(1b)E₂E₄ E_(v)E_(vi) 19 E_(1a)E₂E₃E₄ E_(v)E_(vi) 20 E_(1b)E₂E₃E₄ E_(v)E_(vi) 21 E_(1a)E₂E_(i)E₄ E_(v)E_(vi) 22 E_(1b)E₂E_(i)E₄ E_(v)E_(vi) 23 E_(1a)E₂E_(ii)E₄ E_(v)E_(vi) 24 E_(1b)E₂E_(ii)E₄ E_(v)E_(vi) 25 E_(1a)E₂E_(ii)E_(iib)E₄ E_(v)E_(vi) 26 E_(1b)E₂E_(ii)E_(iib)E₄ E_(v)E_(vi) 27 E_(1a)E₂E₃E_(i)E₄ E_(v)E_(vi) 28 E_(1b)E₂E₃E_(i)E₄ E_(v)E_(vi) 29 E_(1a)E₂E₃E_(ii)E₄ E_(v)E_(vi) 30 E_(1b)E₂E₃E_(ii)E₄ E_(v)E_(vi) 31 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E_(v)E_(vi) 32 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E_(v)E_(vi) 33 E_(1a)E₂E_(iii) E_(v)E_(vi) 34 E_(1b)E₂E_(iii) E_(v)E_(vi) 35 E_(1a)E₂E₃E_(iii) E_(v)E_(vi) 36 E_(1b)E₂E₃E_(iii) E_(v)E_(vi) 37 E_(1a)E₂E_(iii)E₄ E_(v)E_(vi) 38 E_(1b)E₂E_(iii)E₄ E_(v)E_(vi) 39 E_(1a)E₂E₃E_(iii)E₄ E_(v)E_(vi) 40 E_(1b)E₂E₃E_(iii)E₄ E_(v)E_(vi) 41 E_(1a)E₂E_(iv) E_(v)E_(vi) 42 E_(1b)E₂E_(iv) E_(v)E_(vi) 43 E_(1a)E₂E₃E_(iv) E_(v)E_(vi) 44 E_(1b)E₂E₃E_(iv) E_(v)E_(vi) 45 E_(1a)E₂E_(iv)E₄ E_(v)E_(vi) 46 E_(1b)E₂E_(iv)E₄ E_(v)E_(vi) 47 E_(1a)E₂E₃E_(iv)E₄ E_(v)E_(vi) 48 E_(1b)E₂E₃E_(iv)E₄ E_(v)E_(vi) 49 E_(1a)E₂ E_(v)E_(vi) E₄* 50 E_(1b)E₂ E_(v)E_(vi) E₄* 51 E_(1a)E₂E₃ E_(v)E_(vi) E₄* 52 E_(1b)E₂E₃ E_(v)E_(vi) E₄* 53 E_(1a)E₂E_(i) E_(v)E_(vi) E₄* 54 E_(1b)E₂E_(i) E_(v)E_(vi) E₄* 55 E_(1a)E₂E_(ii) E_(v)E_(vi) E₄* 56 E_(1b)E₂E_(ii) E_(v)E_(vi) E₄* 57 E_(1a)E₂E_(ii)E_(iib) E_(v)E_(vi) E₄* 58 E_(1b)E₂E_(ii)E_(iib) E_(v)E_(vi) E₄* 59 E_(1a)E₂E₃E_(i) E_(v)E_(vi) E₄* 60 E_(1b)E₂E₃E_(i) E_(v)E_(vi) E₄* 61 E_(1a)E₂E₃E_(ii) E_(v)E_(vi) E₄* 62 E_(1b)E₂E₃E_(ii) E_(v)E_(vi) E₄* 63 E_(1a)E₂E₃E_(ii)E_(iib) E_(v)E_(vi) E₄* 64 E_(1b)E₂E₃E_(ii)E_(iib) E_(v)E_(vi) E₄* 65 E_(1a)E₂E₄ E_(v)E_(vi) E₄* 66 E_(1b)E₂E₄ E_(v)E_(vi) E₄* 67 E_(1a)E₂E₃E₄ E_(v)E_(vi) E₄* 68 E_(1b)E₂E₃E₄ E_(v)E_(vi) E₄* 69 E_(1a)E₂E_(i)E₄ E_(v)E_(vi) E₄* 70 E_(1b)E₂E_(i)E₄ E_(v)E_(vi) E₄* 71 E_(1a)E₂E_(ii)E₄ E_(v)E_(vi) E₄* 72 E_(1b)E₂E_(ii)E₄ E_(v)E_(vi) E₄* 73 E_(1a)E₂E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* 74 E_(1b)E₂E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* 75 E_(1a)E₂E₃E_(i)E₄ E_(v)E_(vi) E₄* 76 E_(1b)E₂E₃E_(i)E₄ E_(v)E_(vi) E₄* 77 E_(1a)E₂E₃E_(ii)E₄ E_(v)E_(vi) E₄* 78 E_(1b)E₂E₃E_(ii)E₄ E_(v)E_(vi) E₄* 79 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* 80 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* 81 E_(1a)E₂E_(iii) E_(v)E_(vi) E₄* 82 E_(1b)E₂E_(iii) E_(v)E_(vi) E₄* 83 E_(1a)E₂E₃E_(iii) E_(v)E_(vi) E₄* 84 E_(1b)E₂E₃E_(iii) E_(v)E_(vi) E₄* 85 E_(1a)E₂E_(iii)E₄ E_(v)E_(vi) E₄* 86 E_(1b)E₂E_(iii)E₄ E_(v)E_(vi) E₄* 87 E_(1a)E₂E₃E_(iii)E₄ E_(v)E_(vi) E₄* 88 E_(1b)E₂E₃E_(iii)E₄ E_(v)E_(vi) E₄* 89 E_(1a)E₂E_(iv) E_(v)E_(vi) E₄* 90 E_(1b)E₂E_(iv) E_(v)E_(vi) E₄* 91 E_(1a)E₂E₃E_(iv) E_(v)E_(vi) E₄* 92 E_(1b)E₂E₃E_(iv) E_(v)E_(vi) E₄* 93 E_(1a)E₂E_(iv)E₄ E_(v)E_(vi) E₄* 94 E_(1b)E₂E_(iv)E₄ E_(v)E_(vi) E₄* 95 E_(1a)E₂E₃E_(iv)E₄ E_(v)E_(vi) E₄* 96 E_(1b)E₂E₃E_(iv)E₄ E_(v)E_(vi) E₄* 97 E_(1a)E₂ E_(v)E_(vi) E₅ 98 E_(1b)E₂ E_(v)E_(vi) E₅ 99 E_(1a)E₂E₃ E_(v)E_(vi) E₅ 100 E_(1b)E₂E₃ E_(v)E_(vi) E₅ 101 E_(1a)E₂E_(i) E_(v)E_(vi) E₅ 102 E_(1b)E₂E_(i) E_(v)E_(vi) E₅ 103 E_(1a)E₂E_(ii) E_(v)E_(vi) E₅ 104 E_(1b)E₂E_(ii) E_(v)E_(vi) E₅ 105 E_(1a)E₂E_(ii)E_(iib) E_(v)E_(vi) E₅ 106 E_(1b)E₂E_(ii)E_(iib) E_(v)E_(vi) E₅ 107 E_(1a)E₂E₃E_(i) E_(v)E_(vi) E₅ 108 E_(1b)E₂E₃E_(i) E_(v)E_(vi) E₅ 109 E_(1a)E₂E₃E_(ii) E_(v)E_(vi) E₅ 110 E_(1b)E₂E₃E_(ii) E_(v)E_(vi) E₅ 111 E_(1a)E₂E₃E_(ii)E_(iib) E_(v)E_(vi) E₅ 112 E_(1b)E₂E₃E_(ii)E_(iib) E_(v)E_(vi) E₅ 113 E_(1a)E₂E₄ E_(v)E_(vi) E₅ 114 E_(1b)E₂E₄ E_(v)E_(vi) E₅ 115 E_(1a)E₂E₃E₄ E_(v)E_(vi) E₅ 116 E_(1b)E₂E₃E₄ E_(v)E_(vi) E₅ 117 E_(1a)E₂E_(i)E₄ E_(v)E_(vi) E₅ 118 E_(1b)E₂E_(i)E₄ E_(v)E_(vi) E₅ 119 E_(1a)E₂E_(ii)E₄ E_(v)E_(vi) E₅ 120 E_(1b)E₂E_(ii)E₄ E_(v)E_(vi) E₅ 121 E_(1a)E₂E_(ii)E_(iib)E₄ E_(v)E_(vi) E₅ 122 E_(1b)E₂E_(ii)E_(iib)E₄ E_(v)E_(vi) E₅ 123 E_(1a)E₂E₃E_(i)E₄ E_(v)E_(vi) E₅ 124 E_(1b)E₂E₃E_(i)E₄ E_(v)E_(vi) E₅ 125 E_(1a)E₂E₃E_(ii)E₄ E_(v)E_(vi) E₅ 126 E_(1b)E₂E₃E_(ii)E₄ E_(v)E_(vi) E₅ 127 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E_(v)E_(vi) E₅ 128 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E_(v)E_(vi) E₅ 129 E_(1a)E₂E_(iii) E_(v)E_(vi) E₅ 130 E_(1b)E₂E_(iii) E_(v)E_(vi) E₅ 131 E_(1a)E₂E₃E_(iii) E_(v)E_(vi) E₅ 132 E_(1b)E₂E₃E_(iii) E_(v)E_(vi) E₅ 133 E_(1a)E₂E_(iii)E₄ E_(v)E_(vi) E₅ 134 E_(1b)E₂E_(iii)E₄ E_(v)E_(vi) E₅ 135 E_(1a)E₂E₃E_(iii)E₄ E_(v)E_(vi) E₅ 136 E_(1b)E₂E₃E_(iii)E₄ E_(v)E_(vi) E₅ 137 E_(1a)E₂E_(iv) E_(v)E_(vi) E₅ 138 E_(1b)E₂E_(iv) E_(v)E_(vi) E₅ 139 E_(1a)E₂E₃E_(iv) E_(v)E_(vi) E₅ 140 E_(1b)E₂E₃E_(iv) E_(v)E_(vi) E₅ 141 E_(1a)E₂E_(iv)E₄ E_(v)E_(vi) E₅ 142 E_(1b)E₂E_(iv)E₄ E_(v)E_(vi) E₅ 143 E_(1a)E₂E₃E_(iv)E₄ E_(v)E_(vi) E₅ 144 E_(1b)E₂E₃E_(iv)E₄ E_(v)E_(vi) E₅ 145 E_(1a)E₂ E_(v)E_(vi) E₄*E₅ 146 E_(1b)E₂ E_(v)E_(vi) E₄*E₅ 147 E_(1a)E₂E₃ E_(v)E_(vi) E₄*E₅ 148 E_(1b)E₂E₃ E_(v)E_(vi) E₄*E₅ 149 E_(1a)E₂E_(i) E_(v)E_(vi) E₄*E₅ 150 E_(1b)E₂E_(i) E_(v)E_(vi) E₄*E₅ 151 E_(1a)E₂E_(ii) E_(v)E_(vi) E₄*E₅ 152 E_(1b)E₂E_(ii) E_(v)E_(vi) E₄*E₅ 153 E_(1a)E₂E_(ii)E_(iib) E_(v)E_(vi) E₄*E₅ 154 E_(1b)E₂E_(ii)E_(iib) E_(v)E_(vi) E₄*E₅ 155 E_(1a)E₂E₃E_(i) E_(v)E_(vi) E₄*E₅ 156 E_(1b)E₂E₃E_(i) E_(v)E_(vi) E₄*E₅ 157 E_(1a)E₂E₃E_(ii) E_(v)E_(vi) E₄*E₅ 158 E_(1b)E₂E₃E_(ii) E_(v)E_(vi) E₄*E₅ 159 E_(1a)E₂E₃E_(ii)E_(iib) E_(v)E_(vi) E₄*E₅ 160 E_(1b)E₂E₃E_(ii)E_(iib) E_(v)E_(vi) E₄*E₅ 161 E_(1a)E₂E₄ E_(v)E_(vi) E₄*E₅ 162 E_(1b)E₂E₄ E_(v)E_(vi) E₄*E₅ 163 E_(1a)E₂E₃E₄ E_(v)E_(vi) E₄*E₅ 164 E_(1b)E₂E₃E₄ E_(v)E_(vi) E₄*E₅ 165 E_(1a)E₂E_(i)E₄ E_(v)E_(vi) E₄*E₅ 166 E_(1b)E₂E_(i)E₄ E_(v)E_(vi) E₄*E₅ 167 E_(1a)E₂E_(ii)E₄ E_(v)E_(vi) E₄*E₅ 168 E_(1b)E₂E_(ii)E₄ E_(v)E_(vi) E₄*E₅ 169 E_(1a)E₂E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄*E₅ 170 E_(1b)E₂E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄*E₅ 171 E_(1a)E₂E₃E_(i)E₄ E_(v)E_(vi) E₄*E₅ 172 E_(1b)E₂E₃E_(i)E₄ E_(v)E_(vi) E₄*E₅ 173 E_(1a)E₂E₃E_(ii)E₄ E_(v)E_(vi) E₄*E₅ 174 E_(1b)E₂E₃E_(ii)E₄ E_(v)E_(vi) E₄*E₅ 175 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄*E₅ 176 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄*E₅ 177 E_(1a)E₂E_(iii) E_(v)E_(vi) E₄*E₅ 178 E_(1b)E₂E_(iii) E_(v)E_(vi) E₄*E₅ 179 E_(1a)E₂E₃E_(iii) E_(v)E_(vi) E₄*E₅ 180 E_(1b)E₂E₃E_(iii) E_(v)E_(vi) E₄*E₅ 181 E_(1a)E₂E_(iii)E₄ E_(v)E_(vi) E₄*E₅ 182 E_(1b)E₂E_(iii)E₄ E_(v)E_(vi) E₄*E₅ 183 E_(1a)E₂E₃E_(iii)E₄ E_(v)E_(vi) E₄*E₅ 184 E_(1b)E₂E₃E_(iii)E₄ E_(v)E_(vi) E₄*E₅ 185 E_(1a)E₂E_(iv) E_(v)E_(vi) E₄*E₅ 186 E_(1b)E₂E_(iv) E_(v)E_(vi) E₄*E₅ 187 E_(1a)E₂E₃E_(iv) E_(v)E_(vi) E₄*E₅ 188 E_(1b)E₂E₃E_(iv) E_(v)E_(vi) E₄*E₅ 189 E_(1a)E₂E_(iv)E₄ E_(v)E_(vi) E₄*E₅ 190 E_(1b)E₂E_(iv)E₄ E_(v)E_(vi) E₄*E₅ 191 E_(1a)E₂E₃E_(iv)E₄ E_(v)E_(vi) E₄*E₅ 192 E_(1b)E₂E₃E_(iv)E₄ E_(v)E_(vi) E₄*E₅ 193 E_(1a)E₂ AlkLE_(v)E_(vi) 194 E_(1b)E₂ AlkLE_(v)E_(vi) 195 E_(1a)E₂E₃ AlkLE_(v)E_(vi) 196 E_(1b)E₂E₃ AlkLE_(v)E_(vi) 197 E_(1a)E₂E_(i) AlkLE_(v)E_(vi) 198 E_(1b)E₂E_(i) AlkLE_(v)E_(vi) 199 E_(1a)E₂E_(ii) AlkLE_(v)E_(vi) 200 E_(1b)E₂E_(ii) AlkLE_(v)E_(vi) 201 E_(1a)E₂E_(ii)E_(iib) AlkLE_(v)E_(vi) 202 E_(1b)E₂E_(ii)E_(iib) AlkLE_(v)E_(vi) 203 E_(1a)E₂E₃E_(i) AlkLE_(v)E_(vi) 204 E_(1b)E₂E₃E_(i) AlkLE_(v)E_(vi) 205 E_(1a)E₂E₃E_(ii) AlkLE_(v)E_(vi) 206 E_(1b)E₂E₃E_(ii) AlkLE_(v)E_(vi) 207 E_(1a)E₂E₃E_(ii)E_(iib) AlkLE_(v)E_(vi) 208 E_(1b)E₂E₃E_(ii)E_(iib) AlkLE_(v)E_(vi) 209 E_(1a)E₂E₄ AlkLE_(v)E_(vi) 210 E_(1b)E₂E₄ AlkLE_(v)E_(vi) 211 E_(1a)E₂E₃E₄ AlkLE_(v)E_(vi) 212 E_(1b)E₂E₃E₄ AlkLE_(v)E_(vi) 213 E_(1a)E₂E_(i)E₄ AlkLE_(v)E_(vi) 214 E_(1b)E₂E_(i)E₄ AlkLE_(v)E_(vi) 215 E_(1a)E₂E_(ii)E₄ AlkLE_(v)E_(vi) 216 E_(1b)E₂E_(ii)E₄ AlkLE_(v)E_(vi) 217 E_(1a)E₂E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) 218 E_(1b)E₂E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) 219 E_(1a)E₂E₃E_(i)E₄ AlkLE_(v)E_(vi) 220 E_(1b)E₂E₃E_(i)E₄ AlkLE_(v)E_(vi) 221 E_(1a)E₂E₃E_(ii)E₄ AlkLE_(v)E_(vi) 222 E_(1b)E₂E₃E_(ii)E₄ AlkLE_(v)E_(vi) 223 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) 224 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) 225 E_(1a)E₂E_(iii) AlkLE_(v)E_(vi) 226 E_(1b)E₂E_(iii) AlkLE_(v)E_(vi) 227 E_(1a)E₂E₃E_(iii) AlkLE_(v)E_(vi) 228 E_(1b)E₂E₃E_(iii) AlkLE_(v)E_(vi) 229 E_(1a)E₂E_(iii)E₄ AlkLE_(v)E_(vi) 230 E_(1b)E₂E_(iii)E₄ AlkLE_(v)E_(vi) 231 E_(1a)E₂E₃E_(iii)E₄ AlkLE_(v)E_(vi) 232 E_(1b)E₂E₃E_(iii)E₄ AlkLE_(v)E_(vi) 233 E_(1a)E₂E_(iv) AlkLE_(v)E_(vi) 234 E_(1b)E₂E_(iv) AlkLE_(v)E_(vi) 235 E_(1a)E₂E₃E_(iv) AlkLE_(v)E_(vi) 236 E_(1b)E₂E₃E_(iv) AlkLE_(v)E_(vi) 237 E_(1a)E₂E_(iv)E₄ AlkLE_(v)E_(vi) 238 E_(1b)E₂E_(iv)E₄ AlkLE_(v)E_(vi) 239 E_(1a)E₂E₃E_(iv)E₄ AlkLE_(v)E_(vi) 240 E_(1b)E₂E₃E_(iv)E₄ AlkLE_(v)E_(vi) 241 E_(1a)E₂ AlkLE_(v)E_(vi) E₄* 242 E_(1b)E₂ AlkLE_(v)E_(vi) E₄* 243 E_(1a)E₂E₃ AlkLE_(v)E_(vi) E₄* 244 E_(1b)E₂E₃ AlkLE_(v)E_(vi) E₄* 245 E_(1a)E₂E_(i) AlkLE_(v)E_(vi) E₄* 246 E_(1b)E₂E_(i) AlkLE_(v)E_(vi) E₄* 247 E_(1a)E₂E_(ii) AlkLE_(v)E_(vi) E₄* 248 E_(1b)E₂E_(ii) AlkLE_(v)E_(vi) E₄* 249 E_(1a)E₂E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* 250 E_(1b)E₂E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* 251 E_(1a)E₂E₃E_(i) AlkLE_(v)E_(vi) E₄* 252 E_(1b)E₂E₃E_(i) AlkLE_(v)E_(vi) E₄* 253 E_(1a)E₂E₃E_(ii) AlkLE_(v)E_(vi) E₄* 254 E_(1b)E₂E₃E_(ii) AlkLE_(v)E_(vi) E₄* 255 E_(1a)E₂E₃E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* 256 E_(1b)E₂E₃E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* 257 E_(1a)E₂E₄ AlkLE_(v)E_(vi) E₄* 258 E_(1b)E₂E₄ AlkLE_(v)E_(vi) E₄* 259 E_(1a)E₂E₃E₄ AlkLE_(v)E_(vi) E₄* 260 E_(1b)E₂E₃E₄ AlkLE_(v)E_(vi) E₄* 261 E_(1a)E₂E_(i)E₄ AlkLE_(v)E_(vi) E₄* 262 E_(1b)E₂E_(i)E₄ AlkLE_(v)E_(vi) E₄* 263 E_(1a)E₂E_(ii)E₄ AlkLE_(v)E_(vi) E₄* 264 E_(1b)E₂E_(ii)E₄ AlkLE_(v)E_(vi) E₄* 265 E_(1a)E₂E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* 266 E_(1b)E₂E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* 267 E_(1a)E₂E₃E_(i)E₄ AlkLE_(v)E_(vi) E₄* 268 E_(1b)E₂E₃E_(i)E₄ AlkLE_(v)E_(vi) E₄* 269 E_(1a)E₂E₃E_(ii)E₄ AlkLE_(v)E_(vi) E₄* 270 E_(1b)E₂E₃E_(ii)E₄ AlkLE_(v)E_(vi) E₄* 271 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* 272 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* 273 E_(1a)E₂E_(iii) AlkLE_(v)E_(vi) E₄* 274 E_(1b)E₂E_(iii) AlkLE_(v)E_(vi) E₄* 275 E_(1a)E₂E₃E_(iii) AlkLE_(v)E_(vi) E₄* 276 E_(1b)E₂E₃E_(iii) AlkLE_(v)E_(vi) E₄* 277 E_(1a)E₂E_(iii)E₄ AlkLE_(v)E_(vi) E₄* 278 E_(1b)E₂E_(iii)E₄ AlkLE_(v)E_(vi) E₄* 279 E_(1a)E₂E₃E_(iii)E₄ AlkLE_(v)E_(vi) E₄* 280 E_(1b)E₂E₃E_(iii)E₄ AlkLE_(v)E_(vi) E₄* 281 E_(1a)E₂E_(iv) AlkLE_(v)E_(vi) E₄* 282 E_(1b)E₂E_(iv) AlkLE_(v)E_(vi) E₄* 283 E_(1a)E₂E₃E_(iv) AlkLE_(v)E_(vi) E₄* 284 E_(1b)E₂E₃E_(iv) AlkLE_(v)E_(vi) E₄* 285 E_(1a)E₂E_(iv)E₄ AlkLE_(v)E_(vi) E₄* 286 E_(1b)E₂E_(iv)E₄ AlkLE_(v)E_(vi) E₄* 287 E_(1a)E₂E₃E_(iv)E₄ AlkLE_(v)E_(vi) E₄* 288 E_(1b)E₂E₃E_(iv)E₄ AlkLE_(v)E_(vi) E₄* 289 E_(1a)E₂ AlkLE_(v)E_(vi) E₅ 290 E_(1b)E₂ AlkLE_(v)E_(vi) E₅ 291 E_(1a)E₂E₃ AlkLE_(v)E_(vi) E₅ 292 E_(1b)E₂E₃ AlkLE_(v)E_(vi) E₅ 293 E_(1a)E₂E_(i) AlkLE_(v)E_(vi) E₅ 294 E_(1b)E₂E_(i) AlkLE_(v)E_(vi) E₅ 295 E_(1a)E₂E_(ii) AlkLE_(v)E_(vi) E₅ 296 E_(1b)E₂E_(ii) AlkLE_(v)E_(vi) E₅ 297 E_(1a)E₂E_(ii)E_(iib) AlkLE_(v)E_(vi) E₅ 298 E_(1b)E₂E_(ii)E_(iib) AlkLE_(v)E_(vi) E₅ 299 E_(1a)E₂E₃E_(i) AlkLE_(v)E_(vi) E₅ 300 E_(1b)E₂E₃E_(i) AlkLE_(v)E_(vi) E₅ 301 E_(1a)E₂E₃E_(ii) AlkLE_(v)E_(vi) E₅ 302 E_(1b)E₂E₃E_(ii) AlkLE_(v)E_(vi) E₅ 303 E_(1a)E₂E₃E_(ii)E_(iib) AlkLE_(v)E_(vi) E₅ 304 E_(1b)E₂E₃E_(ii)E_(iib) AlkLE_(v)E_(vi) E₅ 305 E_(1a)E₂E₄ AlkLE_(v)E_(vi) E₅ 306 E_(1b)E₂E₄ AlkLE_(v)E_(vi) E₅ 307 E_(1a)E₂E₃E₄ AlkLE_(v)E_(vi) E₅ 308 E_(1b)E₂E₃E₄ AlkLE_(v)E_(vi) E₅ 309 E_(1a)E₂E_(i)E₄ AlkLE_(v)E_(vi) E₅ 310 E_(1b)E₂E_(i)E₄ AlkLE_(v)E_(vi) E₅ 311 E_(1a)E₂E_(ii)E₄ AlkLE_(v)E_(vi) E₅ 312 E_(1b)E₂E_(ii)E₄ AlkLE_(v)E_(vi) E₅ 313 E_(1a)E₂E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₅ 314 E_(1b)E₂E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₅ 315 E_(1a)E₂E₃E_(i)E₄ AlkLE_(v)E_(vi) E₅ 316 E_(1b)E₂E₃E_(i)E₄ AlkLE_(v)E_(vi) E₅ 317 E_(1a)E₂E₃E_(ii)E₄ AlkLE_(v)E_(vi) E₅ 318 E_(1b)E₂E₃E_(ii)E₄ AlkLE_(v)E_(vi) E₅ 319 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₅ 320 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₅ 321 E_(1a)E₂E_(iii) AlkLE_(v)E_(vi) E₅ 322 E_(1b)E₂E_(iii) AlkLE_(v)E_(vi) E₅ 323 E_(1a)E₂E₃E_(iii) AlkLE_(v)E_(vi) E₅ 324 E_(1b)E₂E₃E_(iii) AlkLE_(v)E_(vi) E₅ 325 E_(1a)E₂E_(iii)E₄ AlkLE_(v)E_(vi) E₅ 326 E_(1b)E₂E_(iii)E₄ AlkLE_(v)E_(vi) E₅ 327 E_(1a)E₂E₃E_(iii)E₄ AlkLE_(v)E_(vi) E₅ 328 E_(1b)E₂E₃E_(iii)E₄ AlkLE_(v)E_(vi) E₅ 329 E_(1a)E₂E_(iv) AlkLE_(v)E_(vi) E₅ 330 E_(1b)E₂E_(iv) AlkLE_(v)E_(vi) E₅ 331 E_(1a)E₂E₃E_(iv) AlkLE_(v)E_(vi) E₅ 332 E_(1b)E₂E₃E_(iv) AlkLE_(v)E_(vi) E₅ 333 E_(1a)E₂E_(iv)E₄ AlkLE_(v)E_(vi) E₅ 334 E_(1b)E₂E_(iv)E₄ AlkLE_(v)E_(vi) E₅ 335 E_(1a)E₂E₃E_(iv)E₄ AlkLE_(v)E_(vi) E₅ 336 E_(1b)E₂E₃E_(iv)E₄ AlkLE_(v)E_(vi) E₅ 337 E_(1a)E₂ AlkLE_(v)E_(vi) E₄*E₅ 338 E_(1b)E₂ AlkLE_(v)E_(vi) E₄*E₅ 339 E_(1a)E₂E₃ AlkLE_(v)E_(vi) E₄*E₅ 340 E_(1b)E₂E₃ AlkLE_(v)E_(vi) E₄*E₅ 341 E_(1a)E₂E_(i) AlkLE_(v)E_(vi) E₄*E₅ 342 E_(1b)E₂E_(i) AlkLE_(v)E_(vi) E₄*E₅ 343 E_(1a)E₂E_(ii) AlkLE_(v)E_(vi) E₄*E₅ 344 E_(1b)E₂E_(ii) AlkLE_(v)E_(vi) E₄*E₅ 345 E_(1a)E₂E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄*E₅ 346 E_(1b)E₂E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄*E₅ 347 E_(1a)E₂E₃E_(i) AlkLE_(v)E_(vi) E₄*E₅ 348 E_(1b)E₂E₃E_(i) AlkLE_(v)E_(vi) E₄*E₅ 349 E_(1a)E₂E₃E_(ii) AlkLE_(v)E_(vi) E₄*E₅ 350 E_(1b)E₂E₃E_(ii) AlkLE_(v)E_(vi) E₄*E₅ 351 E_(1a)E₂E₃E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄*E₅ 352 E_(1b)E₂E₃E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄*E₅ 353 E_(1a)E₂E₄ AlkLE_(v)E_(vi) E₄*E₅ 354 E_(1b)E₂E₄ AlkLE_(v)E_(vi) E₄*E₅ 355 E_(1a)E₂E₃E₄ AlkLE_(v)E_(vi) E₄*E₅ 356 E_(1b)E₂E₃E₄ AlkLE_(v)E_(vi) E₄*E₅ 357 E_(1a)E₂E_(i)E₄ AlkLE_(v)E_(vi) E₄*E₅ 358 E_(1b)E₂E_(i)E₄ AlkLE_(v)E_(vi) E₄*E₅ 359 E_(1a)E₂E_(ii)E₄ AlkLE_(v)E_(vi) E₄*E₅ 360 E_(1b)E₂E_(ii)E₄ AlkLE_(v)E_(vi) E₄*E₅ 361 E_(1a)E₂E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄*E₅ 362 E_(1b)E₂E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄*E₅ 363 E_(1a)E₂E₃E_(i)E₄ AlkLE_(v)E_(vi) E₄*E₅ 364 E_(1b)E₂E₃E_(i)E₄ AlkLE_(v)E_(vi) E₄*E₅ 365 E_(1a)E₂E₃E_(ii)E₄ AlkLE_(v)E_(vi) E₄*E₅ 366 E_(1b)E₂E₃E_(ii)E₄ AlkLE_(v)E_(vi) E₄*E₅ 367 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄*E₅ 368 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄*E₅ 369 E_(1a)E₂E_(iii) AlkLE_(v)E_(vi) E₄*E₅ 370 E_(1b)E₂E_(iii) AlkLE_(v)E_(vi) E₄*E₅ 371 E_(1a)E₂E₃E_(iii) AlkLE_(v)E_(vi) E₄*E₅ 372 E_(1b)E₂E₃E_(iii) AlkLE_(v)E_(vi) E₄*E₅ 373 E_(1a)E₂E_(iii)E₄ AlkLE_(v)E_(vi) E₄*E₅ 374 E_(1b)E₂E_(iii)E₄ AlkLE_(v)E_(vi) E₄*E₅ 375 E_(1a)E₂E₃E_(iii)E₄ AlkLE_(v)E_(vi) E₄*E₅ 376 E_(1b)E₂E₃E_(iii)E₄ AlkLE_(v)E_(vi) E₄*E₅ 377 E_(1a)E₂E_(iv) AlkLE_(v)E_(vi) E₄*E₅ 378 E_(1b)E₂E_(iv) AlkLE_(v)E_(vi) E₄*E₅ 379 E_(1a)E₂E₃E_(iv) AlkLE_(v)E_(vi) E₄*E₅ 380 E_(1b)E₂E₃E_(iv) AlkLE_(v)E_(vi) E₄*E₅ 381 E_(1a)E₂E_(iv)E₄ AlkLE_(v)E_(vi) E₄*E₅ 382 E_(1b)E₂E_(iv)E₄ AlkLE_(v)E_(vi) E₄*E₅ 383 E_(1a)E₂E₃E_(iv)E₄ AlkLE_(v)E_(vi) E₄*E₅ 384 E_(1b)E₂E₃E_(iv)E₄ AlkLE_(v)E_(vi) E₄*E₅ 385 E_(1a)E₂ E_(v)E_(vi) E_(a) 386 E_(1b)E₂ E_(v)E_(vi) E_(a) 387 E_(1a)E₂E₃ E_(v)E_(vi) E_(a) 388 E_(1b)E₂E₃ E_(v)E_(vi) E_(a) 389 E_(1a)E₂E_(i) E_(v)E_(vi) E_(a) 390 E_(1b)E₂E_(i) E_(v)E_(vi) E_(a) 391 E_(1a)E₂E_(ii) E_(v)E_(vi) E_(a) 392 E_(1b)E₂E_(ii) E_(v)E_(vi) E_(a) 393 E_(1a)E₂E_(ii)E_(iib) E_(v)E_(vi) E_(a) 394 E_(1b)E₂E_(ii)E_(iib) E_(v)E_(vi) E_(a) 395 E_(1a)E₂E₃E_(i) E_(v)E_(vi) E_(a) 396 E_(1b)E₂E₃E_(i) E_(v)E_(vi) E_(a) 397 E_(1a)E₂E₃E_(ii) E_(v)E_(vi) E_(a) 398 E_(1b)E₂E₃E_(ii) E_(v)E_(vi) E_(a) 399 E_(1a)E₂E₃E_(ii)E_(iib) E_(v)E_(vi) E_(a) 400 E_(1b)E₂E₃E_(ii)E_(iib) E_(v)E_(vi) E_(a) 401 E_(1a)E₂E₄ E_(v)E_(vi) E_(a) 402 E_(1b)E₂E₄ E_(v)E_(vi) E_(a) 403 E_(1a)E₂E₃E₄ E_(v)E_(vi) E_(a) 404 E_(1b)E₂E₃E₄ E_(v)E_(vi) E_(a) 405 E_(1a)E₂E_(i)E₄ E_(v)E_(vi) E_(a) 406 E_(1b)E₂E_(i)E₄ E_(v)E_(vi) E_(a) 407 E_(1a)E₂E_(ii)E₄ E_(v)E_(vi) E_(a) 408 E_(1b)E₂E_(ii)E₄ E_(v)E_(vi) E_(a) 409 E_(1a)E₂E_(ii)E_(iib)E₄ E_(v)E_(vi) E_(a) 410 E_(1b)E₂E_(ii)E_(iib)E₄ E_(v)E_(vi) E_(a) 411 E_(1a)E₂E₃E_(i)E₄ E_(v)E_(vi) E_(a) 412 E_(1b)E₂E₃E_(i)E₄ E_(v)E_(vi) E_(a) 413 E_(1a)E₂E₃E_(ii)E₄ E_(v)E_(vi) E_(a) 414 E_(1b)E₂E₃E_(ii)E₄ E_(v)E_(vi) E_(a) 415 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E_(v)E_(vi) E_(a) 416 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E_(v)E_(vi) E_(a) 417 E_(1a)E₂E_(iii) E_(v)E_(vi) E_(a) 418 E_(1b)E₂E_(iii) E_(v)E_(vi) E_(a) 419 E_(1a)E₂E₃E_(iii) E_(v)E_(vi) E_(a) 420 E_(1b)E₂E₃E_(iii) E_(v)E_(vi) E_(a) 421 E_(1a)E₂E_(iii)E₄ E_(v)E_(vi) E_(a) 422 E_(1b)E₂E_(iii)E₄ E_(v)E_(vi) E_(a) 423 E_(1a)E₂E₃E_(iii)E₄ E_(v)E_(vi) E_(a) 424 E_(1b)E₂E₃E_(iii)E₄ E_(v)E_(vi) E_(a) 425 E_(1a)E₂E_(iv) E_(v)E_(vi) E_(a) 426 E_(1b)E₂E_(iv) E_(v)E_(vi) E_(a) 427 E_(1a)E₂E₃E_(iv) E_(v)E_(vi) E_(a) 428 E_(1b)E₂E₃E_(iv) E_(v)E_(vi) E_(a) 429 E_(1a)E₂E_(iv)E₄ E_(v)E_(vi) E_(a) 430 E_(1b)E₂E_(iv)E₄ E_(v)E_(vi) E_(a) 431 E_(1a)E₂E₃E_(iv)E₄ E_(v)E_(vi) E_(a) 432 E_(1b)E₂E₃E_(iv)E₄ E_(v)E_(vi) E_(a) 433 E_(1a)E₂ E_(v)E_(vi) E₄* E_(a) 434 E_(1b)E₂ E_(v)E_(vi) E₄* E_(a) 435 E_(1a)E₂E₃ E_(v)E_(vi) E₄* E_(a) 436 E_(1b)E₂E₃ E_(v)E_(vi) E₄* E_(a) 437 E_(1a)E₂E_(i) E_(v)E_(vi) E₄* E_(a) 438 E_(1b)E₂E_(i) E_(v)E_(vi) E₄* E_(a) 439 E_(1a)E₂E_(ii) E_(v)E_(vi) E₄* E_(a) 440 E_(1b)E₂E_(ii) E_(v)E_(vi) E₄* E_(a) 441 E_(1a)E₂E_(ii)E_(iib) E_(v)E_(vi) E₄* E_(a) 442 E_(1b)E₂E_(ii)E_(iib) E_(v)E_(vi) E₄* E_(a) 443 E_(1a)E₂E₃E_(i) E_(v)E_(vi) E₄* E_(a) 444 E_(1b)E₂E₃E_(i) E_(v)E_(vi) E₄* E_(a) 445 E_(1a)E₂E₃E_(ii) E_(v)E_(vi) E₄* E_(a) 446 E_(1b)E₂E₃E_(ii) E_(v)E_(vi) E₄* E_(a) 447 E_(1a)E₂E₃E_(ii)E_(iib) E_(v)E_(vi) E₄* E_(a) 448 E_(1b)E₂E₃E_(ii)E_(iib) E_(v)E_(vi) E₄* E_(a) 449 E_(1a)E₂E₄ E_(v)E_(vi) E₄* E_(a) 450 E_(1b)E₂E₄ E_(v)E_(vi) E₄* E_(a) 451 E_(1a)E₂E₃E₄ E_(v)E_(vi) E₄* E_(a) 452 E_(1b)E₂E₃E₄ E_(v)E_(vi) E₄* E_(a) 453 E_(1a)E₂E_(i)E₄ E_(v)E_(vi) E₄* E_(a) 454 E_(1b)E₂E_(i)E₄ E_(v)E_(vi) E₄* E_(a) 455 E_(1a)E₂E_(ii)E₄ E_(v)E_(vi) E₄* E_(a) 456 E_(1b)E₂E_(ii)E₄ E_(v)E_(vi) E₄* E_(a) 457 E_(1a)E₂E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* E_(a) 458 E_(1b)E₂E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* E_(a) 459 E_(1a)E₂E₃E_(i)E₄ E_(v)E_(vi) E₄* E_(a) 460 E_(1b)E₂E₃E_(i)E₄ E_(v)E_(vi) E₄* E_(a) 461 E_(1a)E₂E₃E_(ii)E₄ E_(v)E_(vi) E₄* E_(a) 462 E_(1b)E₂E₃E_(ii)E₄ E_(v)E_(vi) E₄* E_(a) 463 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* E_(a) 464 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* E_(a) 465 E_(1a)E₂E_(iii) E_(v)E_(vi) E₄* E_(a) 466 E_(1b)E₂E_(iii) E_(v)E_(vi) E₄* E_(a) 467 E_(1a)E₂E₃E_(iii) E_(v)E_(vi) E₄* E_(a) 468 E_(1b)E₂E₃E_(iii) E_(v)E_(vi) E₄* E_(a) 469 E_(1a)E₂E_(iii)E₄ E_(v)E_(vi) E₄* E_(a) 470 E_(1b)E₂E_(iii)E₄ E_(v)E_(vi) E₄* E_(a) 471 E_(1a)E₂E₃E_(iii)E₄ E_(v)E_(vi) E₄* E_(a) 472 E_(1b)E₂E₃E_(iii)E₄ E_(v)E_(vi) E₄* E_(a) 473 E_(1a)E₂E_(iv) E_(v)E_(vi) E₄* E_(a) 474 E_(1b)E₂E_(iv) E_(v)E_(vi) E₄* E_(a) 475 E_(1a)E₂E₃E_(iv) E_(v)E_(vi) E₄* E_(a) 476 E_(1b)E₂E₃E_(iv) E_(v)E_(vi) E₄* E_(a) 477 E_(1a)E₂E_(iv)E₄ E_(v)E_(vi) E₄* E_(a) 478 E_(1b)E₂E_(iv)E₄ E_(v)E_(vi) E₄* E_(a) 479 E_(1a)E₂E₃E_(iv)E₄ E_(v)E_(vi) E₄* E_(a) 480 E_(1b)E₂E₃E_(iv)E₄ E_(v)E_(vi) E₄* E_(a) 481 E_(1a)E₂ E_(v)E_(vi) E₅ E_(a) 482 E_(1b)E₂ E_(v)E_(vi) E₅ E_(a) 483 E_(1a)E₂E₃ E_(v)E_(vi) E₅ E_(a) 484 E_(1b)E₂E₃ E_(v)E_(vi) E₅ E_(a) 485 E_(1a)E₂E_(i) E_(v)E_(vi) E₅ E_(a) 486 E_(1b)E₂E_(i) E_(v)E_(vi) E₅ E_(a) 487 E_(1a)E₂E_(ii) E_(v)E_(vi) E₅ E_(a) 488 E_(1b)E₂E_(ii) E_(v)E_(vi) E₅ E_(a) 489 E_(1a)E₂E_(ii)E_(iib) E_(v)E_(vi) E₅ E_(a) 490 E_(1b)E₂E_(ii)E_(iib) E_(v)E_(vi) E₅ E_(a) 491 E_(1a)E₂E₃E_(i) E_(v)E_(vi) E₅ E_(a) 492 E_(1b)E₂E₃E_(i) E_(v)E_(vi) E₅ E_(a) 493 E_(1a)E₂E₃E_(ii) E_(v)E_(vi) E₅ E_(a) 494 E_(1b)E₂E₃E_(ii) E_(v)E_(vi) E₅ E_(a) 495 E_(1a)E₂E₃E_(ii)E_(iib) E_(v)E_(vi) E₅ E_(a) 496 E_(1b)E₂E₃E_(ii)E_(iib) E_(v)E_(vi) E₅ E_(a) 497 E_(1a)E₂E₄ E_(v)E_(vi) E₅ E_(a) 498 E_(1b)E₂E₄ E_(v)E_(vi) E₅ E_(a) 499 E_(1a)E₂E₃E₄ E_(v)E_(vi) E₅ E_(a) 500 E_(1b)E₂E₃E₄ E_(v)E_(vi) E₅ E_(a) 501 E_(1a)E₂E_(i)E₄ E_(v)E_(vi) E₅ E_(a) 502 E_(1b)E₂E_(i)E₄ E_(v)E_(vi) E₅ E_(a) 503 E_(1a)E₂E_(ii)E₄ E_(v)E_(vi) E₅ E_(a) 504 E_(1b)E₂E_(ii)E₄ E_(v)E_(vi) E₅ E_(a) 505 E_(1a)E₂E_(ii)E_(iib)E₄ E_(v)E_(vi) E₅ E_(a) 506 E_(1b)E₂E_(ii)E_(iib)E₄ E_(v)E_(vi) E₅ E_(a) 507 E_(1a)E₂E₃E_(i)E₄ E_(v)E_(vi) E₅ E_(a) 508 E_(1b)E₂E₃E_(i)E₄ E_(v)E_(vi) E₅ E_(a) 509 E_(1a)E₂E₃E_(ii)E₄ E_(v)E_(vi) E₅ E_(a) 510 E_(1b)E₂E₃E_(ii)E₄ E_(v)E_(vi) E₅ E_(a) 511 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E_(v)E_(vi) E₅ E_(a) 512 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E_(v)E_(vi) E₅ E_(a) 513 E_(1a)E₂E_(iii) E_(v)E_(vi) E₅ E_(a) 514 E_(1b)E₂E_(iii) E_(v)E_(vi) E₅ E_(a) 515 E_(1a)E₂E₃E_(iii) E_(v)E_(vi) E₅ E_(a) 516 E_(1b)E₂E₃E_(iii) E_(v)E_(vi) E₅ E_(a) 517 E_(1a)E₂E_(iii)E₄ E_(v)E_(vi) E₅ E_(a) 518 E_(1b)E₂E_(iii)E₄ E_(v)E_(vi) E₅ E_(a) 519 E_(1a)E₂E₃E_(iii)E₄ E_(v)E_(vi) E₅ E_(a) 520 E_(1b)E₂E₃E_(iii)E₄ E_(v)E_(vi) E₅ E_(a) 521 E_(1a)E₂E_(iv) E_(v)E_(vi) E₅ E_(a) 522 E_(1b)E₂E_(iv) E_(v)E_(vi) E₅ E_(a) 523 E_(1a)E₂E₃E_(iv) E_(v)E_(vi) E₅ E_(a) 524 E_(1b)E₂E₃E_(iv) E_(v)E_(vi) E₅ E_(a) 525 E_(1a)E₂E_(iv)E₄ E_(v)E_(vi) E₅ E_(a) 526 E_(1b)E₂E_(iv)E₄ E_(v)E_(vi) E₅ E_(a) 527 E_(1a)E₂E₃E_(iv)E₄ E_(v)E_(vi) E₅ E_(a) 528 E_(1b)E₂E₃E_(iv)E₄ E_(v)E_(vi) E₅ E_(a) 529 E_(1a)E₂ E_(v)E_(vi) E₄*E₅ E_(a) 530 E_(1b)E₂ E_(v)E_(vi) E₄*E₅ E_(a) 531 E_(1a)E₂E₃ E_(v)E_(vi) E₄*E₅ E_(a) 532 E_(1b)E₂E₃ E_(v)E_(vi) E₄*E₅ E_(a) 533 E_(1a)E₂E_(i) E_(v)E_(vi) E₄*E₅ E_(a) 534 E_(1b)E₂E_(i) E_(v)E_(vi) E₄*E₅ E_(a) 535 E_(1a)E₂E_(ii) E_(v)E_(vi) E₄*E₅ E_(a) 536 E_(1b)E₂E_(ii) E_(v)E_(vi) E₄*E₅ E_(a) 537 E_(1a)E₂E_(ii)E_(iib) E_(v)E_(vi) E₄*E₅ E_(a) 538 E_(1b)E₂E_(ii)E_(iib) E_(v)E_(vi) E₄*E₅ E_(a) 539 E_(1a)E₂E₃E_(i) E_(v)E_(vi) E₄*E₅ E_(a) 540 E_(1b)E₂E₃E_(i) E_(v)E_(vi) E₄*E₅ E_(a) 541 E_(1a)E₂E₃E_(ii) E_(v)E_(vi) E₄*E₅ E_(a) 542 E_(1b)E₂E₃E_(ii) E_(v)E_(vi) E₄*E₅ E_(a) 543 E_(1a)E₂E₃E_(ii)E_(iib) E_(v)E_(vi) E₄*E₅ E_(a) 544 E_(1b)E₂E₃E_(ii)E_(iib) E_(v)E_(vi) E₄*E₅ E_(a) 545 E_(1a)E₂E₄ E_(v)E_(vi) E₄*E₅ E_(a) 546 E_(1b)E₂E₄ E_(v)E_(vi) E₄*E₅ E_(a) 547 E_(1a)E₂E₃E₄ E_(v)E_(vi) E₄*E₅ E_(a) 548 E_(1b)E₂E₃E₄ E_(v)E_(vi) E₄*E₅ E_(a) 549 E_(1a)E₂E_(i)E₄ E_(v)E_(vi) E₄*E₅ E_(a) 550 E_(1b)E₂E_(i)E₄ E_(v)E_(vi) E₄*E₅ E_(a) 551 E_(1a)E₂E_(ii)E₄ E_(v)E_(vi) E₄*E₅ E_(a) 552 E_(1b)E₂E_(ii)E₄ E_(v)E_(vi) E₄*E₅ E_(a) 553 E_(1a)E₂E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄*E₅ E_(a) 554 E_(1b)E₂E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄*E₅ E_(a) 555 E_(1a)E₂E₃E_(i)E₄ E_(v)E_(vi) E₄*E₅ E_(a) 556 E_(1b)E₂E₃E_(i)E₄ E_(v)E_(vi) E₄*E₅ E_(a) 557 E_(1a)E₂E₃E_(ii)E₄ E_(v)E_(vi) E₄*E₅ E_(a) 558 E_(1b)E₂E₃E_(ii)E₄ E_(v)E_(vi) E₄*E₅ E_(a) 559 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄*E₅ E_(a) 560 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄*E₅ E_(a) 561 E_(1a)E₂E_(iii) E_(v)E_(vi) E₄*E₅ E_(a) 562 E_(1b)E₂E_(iii) E_(v)E_(vi) E₄*E₅ E_(a) 563 E_(1a)E₂E₃E_(iii) E_(v)E_(vi) E₄*E₅ E_(a) 564 E_(1b)E₂E₃E_(iii) E_(v)E_(vi) E₄*E₅ E_(a) 565 E_(1a)E₂E_(iii)E₄ E_(v)E_(vi) E₄*E₅ E_(a) 566 E_(1b)E₂E_(iii)E₄ E_(v)E_(vi) E₄*E₅ E_(a) 567 E_(1a)E₂E₃E_(iii)E₄ E_(v)E_(vi) E₄*E₅ E_(a) 568 E_(1b)E₂E₃E_(iii)E₄ E_(v)E_(vi) E₄*E₅ E_(a) 569 E_(1a)E₂E_(iv) E_(v)E_(vi) E₄*E₅ E_(a) 570 E_(1b)E₂E_(iv) E_(v)E_(vi) E₄*E₅ E_(a) 571 E_(1a)E₂E₃E_(iv) E_(v)E_(vi) E₄*E₅ E_(a) 572 E_(1b)E₂E₃E_(iv) E_(v)E_(vi) E₄*E₅ E_(a) 573 E_(1a)E₂E_(iv)E₄ E_(v)E_(vi) E₄*E₅ E_(a) 574 E_(1b)E₂E_(iv)E₄ E_(v)E_(vi) E₄*E₅ E_(a) 575 E_(1a)E₂E₃E_(iv)E₄ E_(v)E_(vi) E₄*E₅ E_(a) 576 E_(1b)E₂E₃E_(iv)E₄ E_(v)E_(vi) E₄*E₅ E_(a) 577 E_(1a)E₂ AlkLE_(v)E_(vi) E_(a) 578 E_(1b)E₂ AlkLE_(v)E_(vi) E_(a) 579 E_(1a)E₂E₃ AlkLE_(v)E_(vi) E_(a) 580 E_(1b)E₂E₃ AlkLE_(v)E_(vi) E_(a) 581 E_(1a)E₂E_(i) AlkLE_(v)E_(vi) E_(a) 582 E_(1b)E₂E_(i) AlkLE_(v)E_(vi) E_(a) 583 E_(1a)E₂E_(ii) AlkLE_(v)E_(vi) E_(a) 584 E_(1b)E₂E_(ii) AlkLE_(v)E_(vi) E_(a) 585 E_(1a)E₂E_(ii)E_(iib) AlkLE_(v)E_(vi) E_(a) 586 E_(1b)E₂E_(ii)E_(iib) AlkLE_(v)E_(vi) E_(a) 587 E_(1a)E₂E₃E_(i) AlkLE_(v)E_(vi) E_(a) 588 E_(1b)E₂E₃E_(i) AlkLE_(v)E_(vi) E_(a) 589 E_(1a)E₂E₃E_(ii) AlkLE_(v)E_(vi) E_(a) 590 E_(1b)E₂E₃E_(ii) AlkLE_(v)E_(vi) E_(a) 591 E_(1a)E₂E₃E_(ii)E_(iib) AlkLE_(v)E_(vi) E_(a) 592 E_(1b)E₂E₃E_(ii)E_(iib) AlkLE_(v)E_(vi) E_(a) 593 E_(1a)E₂E₄ AlkLE_(v)E_(vi) E_(a) 594 E_(1b)E₂E₄ AlkLE_(v)E_(vi) E_(a) 595 E_(1a)E₂E₃E₄ AlkLE_(v)E_(vi) E_(a) 596 E_(1b)E₂E₃E₄ AlkLE_(v)E_(vi) E_(a) 597 E_(1a)E₂E_(i)E₄ AlkLE_(v)E_(vi) E_(a) 598 E_(1b)E₂E_(i)E₄ AlkLE_(v)E_(vi) E_(a) 599 E_(1a)E₂E_(ii)E₄ AlkLE_(v)E_(vi) E_(a) 600 E_(1b)E₂E_(ii)E₄ AlkLE_(v)E_(vi) E_(a) 601 E_(1a)E₂E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E_(a) 602 E_(1b)E₂E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E_(a) 603 E_(1a)E₂E₃E_(i)E₄ AlkLE_(v)E_(vi) E_(a) 604 E_(1b)E₂E₃E_(i)E₄ AlkLE_(v)E_(vi) E_(a) 605 E_(1a)E₂E₃E_(ii)E₄ AlkLE_(v)E_(vi) E_(a) 606 E_(1b)E₂E₃E_(ii)E₄ AlkLE_(v)E_(vi) E_(a) 607 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E_(a) 608 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E_(a) 609 E_(1a)E₂E_(iii) AlkLE_(v)E_(vi) E_(a) 610 E_(1b)E₂E_(iii) AlkLE_(v)E_(vi) E_(a) 611 E_(1a)E₂E₃E_(iii) AlkLE_(v)E_(vi) E_(a) 612 E_(1b)E₂E₃E_(iii) AlkLE_(v)E_(vi) E_(a) 613 E_(1a)E₂E_(iii)E₄ AlkLE_(v)E_(vi) E_(a) 614 E_(1b)E₂E_(iii)E₄ AlkLE_(v)E_(vi) E_(a) 615 E_(1a)E₂E₃E_(iii)E₄ AlkLE_(v)E_(vi) E_(a) 616 E_(1b)E₂E₃E_(iii)E₄ AlkLE_(v)E_(vi) E_(a) 617 E_(1a)E₂E_(iv) AlkLE_(v)E_(vi) E_(a) 618 E_(1b)E₂E_(iv) AlkLE_(v)E_(vi) E_(a) 619 E_(1a)E₂E₃E_(iv) AlkLE_(v)E_(vi) E_(a) 620 E_(1b)E₂E₃E_(iv) AlkLE_(v)E_(vi) E_(a) 621 E_(1a)E₂E_(iv)E₄ AlkLE_(v)E_(vi) E_(a) 622 E_(1b)E₂E_(iv)E₄ AlkLE_(v)E_(vi) E_(a) 623 E_(1a)E₂E₃E_(iv)E₄ AlkLE_(v)E_(vi) E_(a) 624 E_(1b)E₂E₃E_(iv)E₄ AlkLE_(v)E_(vi) E_(a) 625 E_(1a)E₂ AlkLE_(v)E_(vi) E₄* E_(a) 626 E_(1b)E₂ AlkLE_(v)E_(vi) E₄* E_(a) 627 E_(1a)E₂E₃ AlkLE_(v)E_(vi) E₄* E_(a) 628 E_(1b)E₂E₃ AlkLE_(v)E_(vi) E₄* E_(a) 629 E_(1a)E₂E_(i) AlkLE_(v)E_(vi) E₄* E_(a) 630 E_(1b)E₂E_(i) AlkLE_(v)E_(vi) E₄* E_(a) 631 E_(1a)E₂E_(ii) AlkLE_(v)E_(vi) E₄* E_(a) 632 E_(1b)E₂E_(ii) AlkLE_(v)E_(vi) E₄* E_(a) 633 E_(1a)E₂E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* E_(a) 634 E_(1b)E₂E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* E_(a) 635 E_(1a)E₂E₃E_(i) AlkLE_(v)E_(vi) E₄* E_(a) 636 E_(1b)E₂E₃E_(i) AlkLE_(v)E_(vi) E₄* E_(a) 637 E_(1a)E₂E₃E_(ii) AlkLE_(v)E_(vi) E₄* E_(a) 638 E_(1b)E₂E₃E_(ii) AlkLE_(v)E_(vi) E₄* E_(a) 639 E_(1a)E₂E₃E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* E_(a) 640 E_(1b)E₂E₃E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* E_(a) 641 E_(1a)E₂E₄ AlkLE_(v)E_(vi) E₄* E_(a) 642 E_(1b)E₂E₄ AlkLE_(v)E_(vi) E₄* E_(a) 643 E_(1a)E₂E₃E₄ AlkLE_(v)E_(vi) E₄* E_(a) 644 E_(1b)E₂E₃E₄ AlkLE_(v)E_(vi) E₄* E_(a) 645 E_(1a)E₂E_(i)E₄ AlkLE_(v)E_(vi) E₄* E_(a) 646 E_(1b)E₂E_(i)E₄ AlkLE_(v)E_(vi) E₄* E_(a) 647 E_(1a)E₂E_(ii)E₄ AlkLE_(v)E_(vi) E₄* E_(a) 648 E_(1b)E₂E_(ii)E₄ AlkLE_(v)E_(vi) E₄* E_(a) 649 E_(1a)E₂E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* E_(a) 650 E_(1b)E₂E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* E_(a) 651 E_(1a)E₂E₃E_(i)E₄ AlkLE_(v)E_(vi) E₄* E_(a) 652 E_(1b)E₂E₃E_(i)E₄ AlkLE_(v)E_(vi) E₄* E_(a) 653 E_(1a)E₂E₃E_(ii)E₄ AlkLE_(v)E_(vi) E₄* E_(a) 654 E_(1b)E₂E₃E_(ii)E₄ AlkLE_(v)E_(vi) E₄* E_(a) 655 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* E_(a) 656 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* E_(a) 657 E_(1a)E₂E_(iii) AlkLE_(v)E_(vi) E₄* E_(a) 658 E_(1b)E₂E_(iii) AlkLE_(v)E_(vi) E₄* E_(a) 659 E_(1a)E₂E₃E_(iii) AlkLE_(v)E_(vi) E₄* E_(a) 660 E_(1b)E₂E₃E_(iii) AlkLE_(v)E_(vi) E₄* E_(a) 661 E_(1a)E₂E_(iii)E₄ AlkLE_(v)E_(vi) E₄* E_(a) 662 E_(1b)E₂E_(iii)E₄ AlkLE_(v)E_(vi) E₄* E_(a) 663 E_(1a)E₂E₃E_(iii)E₄ AlkLE_(v)E_(vi) E₄* E_(a) 664 E_(1b)E₂E₃E_(iii)E₄ AlkLE_(v)E_(vi) E₄* E_(a) 665 E_(1a)E₂E_(iv) AlkLE_(v)E_(vi) E₄* E_(a) 666 E_(1b)E₂E_(iv) AlkLE_(v)E_(vi) E₄* E_(a) 667 E_(1a)E₂E₃E_(iv) AlkLE_(v)E_(vi) E₄* E_(a) 668 E_(1b)E₂E₃E_(iv) AlkLE_(v)E_(vi) E₄* E_(a) 669 E_(1a)E₂E_(iv)E₄ AlkLE_(v)E_(vi) E₄* E_(a) 670 E_(1b)E₂E_(iv)E₄ AlkLE_(v)E_(vi) E₄* E_(a) 671 E_(1a)E₂E₃E_(iv)E₄ AlkLE_(v)E_(vi) E₄* E_(a) 672 E_(1b)E₂E₃E_(iv)E₄ AlkLE_(v)E_(vi) E₄* E_(a) 673 E_(1a)E₂ AlkLE_(v)E_(vi) E₅ E_(a) 674 E_(1b)E₂ AlkLE_(v)E_(vi) E₅ E_(a) 675 E_(1a)E₂E₃ AlkLE_(v)E_(vi) E₅ E_(a) 676 E_(1b)E₂E₃ AlkLE_(v)E_(vi) E₅ E_(a) 677 E_(1a)E₂E_(i) AlkLE_(v)E_(vi) E₅ E_(a) 678 E_(1b)E₂E_(i) AlkLE_(v)E_(vi) E₅ E_(a) 679 E_(1a)E₂E_(ii) AlkLE_(v)E_(vi) E₅ E_(a) 680 E_(1b)E₂E_(ii) AlkLE_(v)E_(vi) E₅ E_(a) 681 E_(1a)E₂E_(ii)E_(iib) AlkLE_(v)E_(vi) E₅ E_(a) 682 E_(1b)E₂E_(ii)E_(iib) AlkLE_(v)E_(vi) E₅ E_(a) 683 E_(1a)E₂E₃E_(i) AlkLE_(v)E_(vi) E₅ E_(a) 684 E_(1b)E₂E₃E_(i) AlkLE_(v)E_(vi) E₅ E_(a) 685 E_(1a)E₂E₃E_(ii) AlkLE_(v)E_(vi) E₅ E_(a) 686 E_(1b)E₂E₃E_(ii) AlkLE_(v)E_(vi) E₅ E_(a) 687 E_(1a)E₂E₃E_(ii)E_(iib) AlkLE_(v)E_(vi) E₅ E_(a) 688 E_(1b)E₂E₃E_(ii)E_(iib) AlkLE_(v)E_(vi) E₅ E_(a) 689 E_(1a)E₂E₄ AlkLE_(v)E_(vi) E₅ E_(a) 690 E_(1b)E₂E₄ AlkLE_(v)E_(vi) E₅ E_(a) 691 E_(1a)E₂E₃E₄ AlkLE_(v)E_(vi) E₅ E_(a) 692 E_(1b)E₂E₃E₄ AlkLE_(v)E_(vi) E₅ E_(a) 693 E_(1a)E₂E_(i)E₄ AlkLE_(v)E_(vi) E₅ E_(a) 694 E_(1b)E₂E_(i)E₄ AlkLE_(v)E_(vi) E₅ E_(a) 695 E_(1a)E₂E_(ii)E₄ AlkLE_(v)E_(vi) E₅ E_(a) 696 E_(1b)E₂E_(ii)E₄ AlkLE_(v)E_(vi) E₅ E_(a) 697 E_(1a)E₂E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₅ E_(a) 698 E_(1b)E₂E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₅ E_(a) 699 E_(1a)E₂E₃E_(i)E₄ AlkLE_(v)E_(vi) E₅ E_(a) 700 E_(1b)E₂E₃E_(i)E₄ AlkLE_(v)E_(vi) E₅ E_(a) 701 E_(1a)E₂E₃E_(ii)E₄ AlkLE_(v)E_(vi) E₅ E_(a) 702 E_(1b)E₂E₃E_(ii)E₄ AlkLE_(v)E_(vi) E₅ E_(a) 703 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₅ E_(a) 704 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₅ E_(a) 705 E_(1a)E₂E_(iii) AlkLE_(v)E_(vi) E₅ E_(a) 706 E_(1b)E₂E_(iii) AlkLE_(v)E_(vi) E₅ E_(a) 707 E_(1a)E₂E₃E_(iii) AlkLE_(v)E_(vi) E₅ E_(a) 708 E_(1b)E₂E₃E_(iii) AlkLE_(v)E_(vi) E₅ E_(a) 709 E_(1a)E₂E_(iii)E₄ AlkLE_(v)E_(vi) E₅ E_(a) 710 E_(1b)E₂E_(iii)E₄ AlkLE_(v)E_(vi) E₅ E_(a) 711 E_(1a)E₂E₃E_(iii)E₄ AlkLE_(v)E_(vi) E₅ E_(a) 712 E_(1b)E₂E₃E_(iii)E₄ AlkLE_(v)E_(vi) E₅ E_(a) 713 E_(1a)E₂E_(iv) AlkLE_(v)E_(vi) E₅ E_(a) 714 E_(1b)E₂E_(iv) AlkLE_(v)E_(vi) E₅ E_(a) 715 E_(1a)E₂E₃E_(iv) AlkLE_(v)E_(vi) E₅ E_(a) 716 E_(1b)E₂E₃E_(iv) AlkLE_(v)E_(vi) E₅ E_(a) 717 E_(1a)E₂E_(iv)E₄ AlkLE_(v)E_(vi) E₅ E_(a) 718 E_(1b)E₂E_(iv)E₄ AlkLE_(v)E_(vi) E₅ E_(a) 719 E_(1a)E₂E₃E_(iv)E₄ AlkLE_(v)E_(vi) E₅ E_(a) 720 E_(1b)E₂E₃E_(iv)E₄ AlkLE_(v)E_(vi) E₅ E_(a) 721 E_(1a)E₂ AlkLE_(v)E_(vi) E₄*E₅ E_(a) 722 E_(1b)E₂ AlkLE_(v)E_(vi) E₄*E₅ E_(a) 723 E_(1a)E₂E₃ AlkLE_(v)E_(vi) E₄*E₅ E_(a) 724 E_(1b)E₂E₃ AlkLE_(v)E_(vi) E₄*E₅ E_(a) 725 E_(1a)E₂E_(i) AlkLE_(v)E_(vi) E₄*E₅ E_(a) 726 E_(1b)E₂E_(i) AlkLE_(v)E_(vi) E₄*E₅ E_(a) 727 E_(1a)E₂E_(ii) AlkLE_(v)E_(vi) E₄*E₅ E_(a) 728 E_(1b)E₂E_(ii) AlkLE_(v)E_(vi) E₄*E₅ E_(a) 729 E_(1a)E₂E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄*E₅ E_(a) 730 E_(1b)E₂E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄*E₅ E_(a) 731 E_(1a)E₂E₃E_(i) AlkLE_(v)E_(vi) E₄*E₅ E_(a) 732 E_(1b)E₂E₃E_(i) AlkLE_(v)E_(vi) E₄*E₅ E_(a) 733 E_(1a)E₂E₃E_(ii) AlkLE_(v)E_(vi) E₄*E₅ E_(a) 734 E_(1b)E₂E₃E_(ii) AlkLE_(v)E_(vi) E₄*E₅ E_(a) 735 E_(1a)E₂E₃E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄*E₅ E_(a) 736 E_(1b)E₂E₃E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄*E₅ E_(a) 737 E_(1a)E₂E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(a) 738 E_(1b)E₂E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(a) 739 E_(1a)E₂E₃E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(a) 740 E_(1b)E₂E₃E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(a) 741 E_(1a)E₂E_(i)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(a) 742 E_(1b)E₂E_(i)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(a) 743 E_(1a)E₂E_(ii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(a) 744 E_(1b)E₂E_(ii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(a) 745 E_(1a)E₂E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(a) 746 E_(1b)E₂E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(a) 747 E_(1a)E₂E₃E_(i)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(a) 748 E_(1b)E₂E₃E_(i)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(a) 749 E_(1a)E₂E₃E_(ii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(a) 750 E_(1b)E₂E₃E_(ii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(a) 751 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(a) 752 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(a) 753 E_(1a)E₂E_(iii) AlkLE_(v)E_(vi) E₄*E₅ E_(a) 754 E_(1b)E₂E_(iii) AlkLE_(v)E_(vi) E₄*E₅ E_(a) 755 E_(1a)E₂E₃E_(iii) AlkLE_(v)E_(vi) E₄*E₅ E_(a) 756 E_(1b)E₂E₃E_(iii) AlkLE_(v)E_(vi) E₄*E₅ E_(a) 757 E_(1a)E₂E_(iii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(a) 758 E_(1b)E₂E_(iii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(a) 759 E_(1a)E₂E₃E_(iii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(a) 760 E_(1b)E₂E₃E_(iii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(a) 761 E_(1a)E₂E_(iv) AlkLE_(v)E_(vi) E₄*E₅ E_(a) 762 E_(1b)E₂E_(iv) AlkLE_(v)E_(vi) E₄*E₅ E_(a) 763 E_(1a)E₂E₃E_(iv) AlkLE_(v)E_(vi) E₄*E₅ E_(a) 764 E_(1b)E₂E₃E_(iv) AlkLE_(v)E_(vi) E₄*E₅ E_(a) 765 E_(1a)E₂E_(iv)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(a) 766 E_(1b)E₂E_(iv)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(a) 767 E_(1a)E₂E₃E_(iv)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(a) 768 E_(1b)E₂E₃E_(iv)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(a) 769 E_(1a)E₂ E_(v)E_(vi) E_(b) 770 E_(1b)E₂ E_(v)E_(vi) E_(b) 771 E_(1a)E₂E₃ E_(v)E_(vi) E_(b) 772 E_(1b)E₂E₃ E_(v)E_(vi) E_(b) 773 E_(1a)E₂E_(i) E_(v)E_(vi) E_(b) 774 E_(1b)E₂E_(i) E_(v)E_(vi) E_(b) 775 E_(1a)E₂E_(ii) E_(v)E_(vi) E_(b) 776 E_(1b)E₂E_(ii) E_(v)E_(vi) E_(b) 777 E_(1a)E₂E_(ii)E_(iib) E_(v)E_(vi) E_(b) 778 E_(1b)E₂E_(ii)E_(iib) E_(v)E_(vi) E_(b) 779 E_(1a)E₂E₃E_(i) E_(v)E_(vi) E_(b) 780 E_(1b)E₂E₃E_(i) E_(v)E_(vi) E_(b) 781 E_(1a)E₂E₃E_(ii) E_(v)E_(vi) E_(b) 782 E_(1b)E₂E₃E_(ii) E_(v)E_(vi) E_(b) 783 E_(1a)E₂E₃E_(ii)E_(iib) E_(v)E_(vi) E_(b) 784 E_(1b)E₂E₃E_(ii)E_(iib) E_(v)E_(vi) E_(b) 785 E_(1a)E₂E₄ E_(v)E_(vi) E_(b) 786 E_(1b)E₂E₄ E_(v)E_(vi) E_(b) 787 E_(1a)E₂E₃E₄ E_(v)E_(vi) E_(b) 788 E_(1b)E₂E₃E₄ E_(v)E_(vi) E_(b) 789 E_(1a)E₂E_(i)E₄ E_(v)E_(vi) E_(b) 790 E_(1b)E₂E_(i)E₄ E_(v)E_(vi) E_(b) 791 E_(1a)E₂E_(ii)E₄ E_(v)E_(vi) E_(b) 792 E_(1b)E₂E_(ii)E₄ E_(v)E_(vi) E_(b) 793 E_(1a)E₂E_(ii)E_(iib)E₄ E_(v)E_(vi) E_(b) 794 E_(1b)E₂E_(ii)E_(iib)E₄ E_(v)E_(vi) E_(b) 795 E_(1a)E₂E₃E_(i)E₄ E_(v)E_(vi) E_(b) 796 E_(1b)E₂E₃E_(i)E₄ E_(v)E_(vi) E_(b) 797 E_(1a)E₂E₃E_(ii)E₄ E_(v)E_(vi) E_(b) 798 E_(1b)E₂E₃E_(ii)E₄ E_(v)E_(vi) E_(b) 799 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E_(v)E_(vi) E_(b) 800 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E_(v)E_(vi) E_(b) 801 E_(1a)E₂E_(iii) E_(v)E_(vi) E_(b) 802 E_(1b)E₂E_(iii) E_(v)E_(vi) E_(b) 803 E_(1a)E₂E₃E_(iii) E_(v)E_(vi) E_(b) 804 E_(1b)E₂E₃E_(iii) E_(v)E_(vi) E_(b) 805 E_(1a)E₂E_(iii)E₄ E_(v)E_(vi) E_(b) 806 E_(1b)E₂E_(iii)E₄ E_(v)E_(vi) E_(b) 807 E_(1a)E₂E₃E_(iii)E₄ E_(v)E_(vi) E_(b) 808 E_(1b)E₂E₃E_(iii)E₄ E_(v)E_(vi) E_(b) 809 E_(1a)E₂E_(iv) E_(v)E_(vi) E_(b) 810 E_(1b)E₂E_(iv) E_(v)E_(vi) E_(b) 811 E_(1a)E₂E₃E_(iv) E_(v)E_(vi) E_(b) 812 E_(1b)E₂E₃E_(iv) E_(v)E_(vi) E_(b) 813 E_(1a)E₂E_(iv)E₄ E_(v)E_(vi) E_(b) 814 E_(1b)E₂E_(iv)E₄ E_(v)E_(vi) E_(b) 815 E_(1a)E₂E₃E_(iv)E₄ E_(v)E_(vi) E_(b) 816 E_(1b)E₂E₃E_(iv)E₄ E_(v)E_(vi) E_(b) 817 E_(1a)E₂ E_(v)E_(vi) E₄* E_(b) 818 E_(1b)E₂ E_(v)E_(vi) E₄* E_(b) 819 E_(1a)E₂E₃ E_(v)E_(vi) E₄* E_(b) 820 E_(1b)E₂E₃ E_(v)E_(vi) E₄* E_(b) 821 E_(1a)E₂E_(i) E_(v)E_(vi) E₄* E_(b) 822 E_(1b)E₂E_(i) E_(v)E_(vi) E₄* E_(b) 823 E_(1a)E₂E_(ii) E_(v)E_(vi) E₄* E_(b) 824 E_(1b)E₂E_(ii) E_(v)E_(vi) E₄* E_(b) 825 E_(1a)E₂E_(ii)E_(iib) E_(v)E_(vi) E₄* E_(b) 826 E_(1b)E₂E_(ii)E_(iib) E_(v)E_(vi) E₄* E_(b) 827 E_(1a)E₂E₃E_(i) E_(v)E_(vi) E₄* E_(b) 828 E_(1b)E₂E₃E_(i) E_(v)E_(vi) E₄* E_(b) 829 E_(1a)E₂E₃E_(ii) E_(v)E_(vi) E₄* E_(b) 830 E_(1b)E₂E₃E_(ii) E_(v)E_(vi) E₄* E_(b) 831 E_(1a)E₂E₃E_(ii)E_(iib) E_(v)E_(vi) E₄* E_(b) 832 E_(1b)E₂E₃E_(ii)E_(iib) E_(v)E_(vi) E₄* E_(b) 833 E_(1a)E₂E₄ E_(v)E_(vi) E₄* E_(b) 834 E_(1b)E₂E₄ E_(v)E_(vi) E₄* E_(b) 835 E_(1a)E₂E₃E₄ E_(v)E_(vi) E₄* E_(b) 836 E_(1b)E₂E₃E₄ E_(v)E_(vi) E₄* E_(b) 837 E_(1a)E₂E_(i)E₄ E_(v)E_(vi) E₄* E_(b) 838 E_(1b)E₂E_(i)E₄ E_(v)E_(vi) E₄* E_(b) 839 E_(1a)E₂E_(ii)E₄ E_(v)E_(vi) E₄* E_(b) 840 E_(1b)E₂E_(ii)E₄ E_(v)E_(vi) E₄* E_(b) 841 E_(1a)E₂E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* E_(b) 842 E_(1b)E₂E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* E_(b) 843 E_(1a)E₂E₃E_(i)E₄ E_(v)E_(vi) E₄* E_(b) 844 E_(1b)E₂E₃E_(i)E₄ E_(v)E_(vi) E₄* E_(b) 845 E_(1a)E₂E₃E_(ii)E₄ E_(v)E_(vi) E₄* E_(b) 846 E_(1b)E₂E₃E_(ii)E₄ E_(v)E_(vi) E₄* E_(b) 847 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* E_(b) 848 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* E_(b) 849 E_(1a)E₂E_(iii) E_(v)E_(vi) E₄* E_(b) 850 E_(1b)E₂E_(iii) E_(v)E_(vi) E₄* E_(b) 851 E_(1a)E₂E₃E_(iii) E_(v)E_(vi) E₄* E_(b) 852 E_(1b)E₂E₃E_(iii) E_(v)E_(vi) E₄* E_(b) 853 E_(1a)E₂E_(iii)E₄ E_(v)E_(vi) E₄* E_(b) 854 E_(1b)E₂E_(iii)E₄ E_(v)E_(vi) E₄* E_(b) 855 E_(1a)E₂E₃E_(iii)E₄ E_(v)E_(vi) E₄* E_(b) 856 E_(1b)E₂E₃E_(iii)E₄ E_(v)E_(vi) E₄* E_(b) 857 E_(1a)E₂E_(iv) E_(v)E_(vi) E₄* E_(b) 858 E_(1b)E₂E_(iv) E_(v)E_(vi) E₄* E_(b) 859 E_(1a)E₂E₃E_(iv) E_(v)E_(vi) E₄* E_(b) 860 E_(1b)E₂E₃E_(iv) E_(v)E_(vi) E₄* E_(b) 861 E_(1a)E₂E_(iv)E₄ E_(v)E_(vi) E₄* E_(b) 862 E_(1b)E₂E_(iv)E₄ E_(v)E_(vi) E₄* E_(b) 863 E_(1a)E₂E₃E_(iv)E₄ E_(v)E_(vi) E₄* E_(b) 864 E_(1b)E₂E₃E_(iv)E₄ E_(v)E_(vi) E₄* E_(b) 865 E_(1a)E₂ E_(v)E_(vi) E₅ E_(b) 866 E_(1b)E₂ E_(v)E_(vi) E₅ E_(b) 867 E_(1a)E₂E₃ E_(v)E_(vi) E₅ E_(b) 868 E_(1b)E₂E₃ E_(v)E_(vi) E₅ E_(b) 869 E_(1a)E₂E_(i) E_(v)E_(vi) E₅ E_(b) 870 E_(1b)E₂E_(i) E_(v)E_(vi) E₅ E_(b) 871 E_(1a)E₂E_(ii) E_(v)E_(vi) E₅ E_(b) 872 E_(1b)E₂E_(ii) E_(v)E_(vi) E₅ E_(b) 873 E_(1a)E₂E_(ii)E_(iib) E_(v)E_(vi) E₅ E_(b) 874 E_(1b)E₂E_(ii)E_(iib) E_(v)E_(vi) E₅ E_(b) 875 E_(1a)E₂E₃E_(i) E_(v)E_(vi) E₅ E_(b) 876 E_(1b)E₂E₃E_(i) E_(v)E_(vi) E₅ E_(b) 877 E_(1a)E₂E₃E_(ii) E_(v)E_(vi) E₅ E_(b) 878 E_(1b)E₂E₃E_(ii) E_(v)E_(vi) E₅ E_(b) 879 E_(1a)E₂E₃E_(ii)E_(iib) E_(v)E_(vi) E₅ E_(b) 880 E_(1b)E₂E₃E_(ii)E_(iib) E_(v)E_(vi) E₅ E_(b) 881 E_(1a)E₂E₄ E_(v)E_(vi) E₅ E_(b) 882 E_(1b)E₂E₄ E_(v)E_(vi) E₅ E_(b) 883 E_(1a)E₂E₃E₄ E_(v)E_(vi) E₅ E_(b) 884 E_(1b)E₂E₃E₄ E_(v)E_(vi) E₅ E_(b) 885 E_(1a)E₂E_(i)E₄ E_(v)E_(vi) E₅ E_(b) 886 E_(1b)E₂E_(i)E₄ E_(v)E_(vi) E₅ E_(b) 887 E_(1a)E₂E_(ii)E₄ E_(v)E_(vi) E₅ E_(b) 888 E_(1b)E₂E_(ii)E₄ E_(v)E_(vi) E₅ E_(b) 889 E_(1a)E₂E_(ii)E_(iib)E₄ E_(v)E_(vi) E₅ E_(b) 890 E_(1b)E₂E_(ii)E_(iib)E₄ E_(v)E_(vi) E₅ E_(b) 891 E_(1a)E₂E₃E_(i)E₄ E_(v)E_(vi) E₅ E_(b) 892 E_(1b)E₂E₃E_(i)E₄ E_(v)E_(vi) E₅ E_(b) 893 E_(1a)E₂E₃E_(ii)E₄ E_(v)E_(vi) E₅ E_(b) 894 E_(1b)E₂E₃E_(ii)E₄ E_(v)E_(vi) E₅ E_(b) 895 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E_(v)E_(vi) E₅ E_(b) 896 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E_(v)E_(vi) E₅ E_(b) 897 E_(1a)E₂E_(iii) E_(v)E_(vi) E₅ E_(b) 898 E_(1b)E₂E_(iii) E_(v)E_(vi) E₅ E_(b) 899 E_(1a)E₂E₃E_(iii) E_(v)E_(vi) E₅ E_(b) 900 E_(1b)E₂E₃E_(iii) E_(v)E_(vi) E₅ E_(b) 901 E_(1a)E₂E_(iii)E₄ E_(v)E_(vi) E₅ E_(b) 902 E_(1b)E₂E_(iii)E₄ E_(v)E_(vi) E₅ E_(b) 903 E_(1a)E₂E₃E_(iii)E₄ E_(v)E_(vi) E₅ E_(b) 904 E_(1b)E₂E₃E_(iii)E₄ E_(v)E_(vi) E₅ E_(b) 905 E_(1a)E₂E_(iv) E_(v)E_(vi) E₅ E_(b) 906 E_(1b)E₂E_(iv) E_(v)E_(vi) E₅ E_(b) 907 E_(1a)E₂E₃E_(iv) E_(v)E_(vi) E₅ E_(b) 908 E_(1b)E₂E₃E_(iv) E_(v)E_(vi) E₅ E_(b) 909 E_(1a)E₂E_(iv)E₄ E_(v)E_(vi) E₅ E_(b) 910 E_(1b)E₂E_(iv)E₄ E_(v)E_(vi) E₅ E_(b) 911 E_(1a)E₂E₃E_(iv)E₄ E_(v)E_(vi) E₅ E_(b) 912 E_(1b)E₂E₃E_(iv)E₄ E_(v)E_(vi) E₅ E_(b) 913 E_(1a)E₂ E_(v)E_(vi) E₄*E₅ E_(b) 914 E_(1b)E₂ E_(v)E_(vi) E₄*E₅ E_(b) 915 E_(1a)E₂E₃ E_(v)E_(vi) E₄*E₅ E_(b) 916 E_(1b)E₂E₃ E_(v)E_(vi) E₄*E₅ E_(b) 917 E_(1a)E₂E_(i) E_(v)E_(vi) E₄*E₅ E_(b) 918 E_(1b)E₂E_(i) E_(v)E_(vi) E₄*E₅ E_(b) 919 E_(1a)E₂E_(ii) E_(v)E_(vi) E₄*E₅ E_(b) 920 E_(1b)E₂E_(ii) E_(v)E_(vi) E₄*E₅ E_(b) 921 E_(1a)E₂E_(ii)E_(iib) E_(v)E_(vi) E₄*E₅ E_(b) 922 E_(1b)E₂E_(ii)E_(iib) E_(v)E_(vi) E₄*E₅ E_(b) 923 E_(1a)E₂E₃E_(i) E_(v)E_(vi) E₄*E₅ E_(b) 924 E_(1b)E₂E₃E_(i) E_(v)E_(vi) E₄*E₅ E_(b) 925 E_(1a)E₂E₃E_(ii) E_(v)E_(vi) E₄*E₅ E_(b) 926 E_(1b)E₂E₃E_(ii) E_(v)E_(vi) E₄*E₅ E_(b) 927 E_(1a)E₂E₃E_(ii)E_(iib) E_(v)E_(vi) E₄*E₅ E_(b) 928 E_(1b)E₂E₃E_(ii)E_(iib) E_(v)E_(vi) E₄*E₅ E_(b) 929 E_(1a)E₂E₄ E_(v)E_(vi) E₄*E₅ E_(b) 930 E_(1b)E₂E₄ E_(v)E_(vi) E₄*E₅ E_(b) 931 E_(1a)E₂E₃E₄ E_(v)E_(vi) E₄*E₅ E_(b) 932 E_(1b)E₂E₃E₄ E_(v)E_(vi) E₄*E₅ E_(b) 933 E_(1a)E₂E_(i)E₄ E_(v)E_(vi) E₄*E₅ E_(b) 934 E_(1b)E₂E_(i)E₄ E_(v)E_(vi) E₄*E₅ E_(b) 935 E_(1a)E₂E_(ii)E₄ E_(v)E_(vi) E₄*E₅ E_(b) 936 E_(1b)E₂E_(ii)E₄ E_(v)E_(vi) E₄*E₅ E_(b) 937 E_(1a)E₂E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄*E₅ E_(b) 938 E_(1b)E₂E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄*E₅ E_(b) 939 E_(1a)E₂E₃E_(i)E₄ E_(v)E_(vi) E₄*E₅ E_(b) 940 E_(1b)E₂E₃E_(i)E₄ E_(v)E_(vi) E₄*E₅ E_(b) 941 E_(1a)E₂E₃E_(ii)E₄ E_(v)E_(vi) E₄*E₅ E_(b) 942 E_(1b)E₂E₃E_(ii)E₄ E_(v)E_(vi) E₄*E₅ E_(b) 943 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄*E₅ E_(b) 944 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄*E₅ E_(b) 945 E_(1a)E₂E_(iii) E_(v)E_(vi) E₄*E₅ E_(b) 946 E_(1b)E₂E_(iii) E_(v)E_(vi) E₄*E₅ E_(b) 947 E_(1a)E₂E₃E_(iii) E_(v)E_(vi) E₄*E₅ E_(b) 948 E_(1b)E₂E₃E_(iii) E_(v)E_(vi) E₄*E₅ E_(b) 949 E_(1a)E₂E_(iii)E₄ E_(v)E_(vi) E₄*E₅ E_(b) 950 E_(1b)E₂E_(iii)E₄ E_(v)E_(vi) E₄*E₅ E_(b) 951 E_(1a)E₂E₃E_(iii)E₄ E_(v)E_(vi) E₄*E₅ E_(b) 952 E_(1b)E₂E₃E_(iii)E₄ E_(v)E_(vi) E₄*E₅ E_(b) 953 E_(1a)E₂E_(iv) E_(v)E_(vi) E₄*E₅ E_(b) 954 E_(1b)E₂E_(iv) E_(v)E_(vi) E₄*E₅ E_(b) 955 E_(1a)E₂E₃E_(iv) E_(v)E_(vi) E₄*E₅ E_(b) 956 E_(1b)E₂E₃E_(iv) E_(v)E_(vi) E₄*E₅ E_(b) 957 E_(1a)E₂E_(iv)E₄ E_(v)E_(vi) E₄*E₅ E_(b) 958 E_(1b)E₂E_(iv)E₄ E_(v)E_(vi) E₄*E₅ E_(b) 959 E_(1a)E₂E₃E_(iv)E₄ E_(v)E_(vi) E₄*E₅ E_(b) 960 E_(1b)E₂E₃E_(iv)E₄ E_(v)E_(vi) E₄*E₅ E_(b) 961 E_(1a)E₂ AlkLE_(v)E_(vi) E_(b) 962 E_(1b)E₂ AlkLE_(v)E_(vi) E_(b) 963 E_(1a)E₂E₃ AlkLE_(v)E_(vi) E_(b) 964 E_(1b)E₂E₃ AlkLE_(v)E_(vi) E_(b) 965 E_(1a)E₂E_(i) AlkLE_(v)E_(vi) E_(b) 966 E_(1b)E₂E_(i) AlkLE_(v)E_(vi) E_(b) 967 E_(1a)E₂E_(ii) AlkLE_(v)E_(vi) E_(b) 968 E_(1b)E₂E_(ii) AlkLE_(v)E_(vi) E_(b) 969 E_(1a)E₂E_(ii)E_(iib) AlkLE_(v)E_(vi) E_(b) 970 E_(1b)E₂E_(ii)E_(iib) AlkLE_(v)E_(vi) E_(b) 971 E_(1a)E₂E₃E_(i) AlkLE_(v)E_(vi) E_(b) 972 E_(1b)E₂E₃E_(i) AlkLE_(v)E_(vi) E_(b) 973 E_(1a)E₂E₃E_(ii) AlkLE_(v)E_(vi) E_(b) 974 E_(1b)E₂E₃E_(ii) AlkLE_(v)E_(vi) E_(b) 975 E_(1a)E₂E₃E_(ii)E_(iib) AlkLE_(v)E_(vi) E_(b) 976 E_(1b)E₂E₃E_(ii)E_(iib) AlkLE_(v)E_(vi) E_(b) 977 E_(1a)E₂E₄ AlkLE_(v)E_(vi) E_(b) 978 E_(1b)E₂E₄ AlkLE_(v)E_(vi) E_(b) 979 E_(1a)E₂E₃E₄ AlkLE_(v)E_(vi) E_(b) 980 E_(1b)E₂E₃E₄ AlkLE_(v)E_(vi) E_(b) 981 E_(1a)E₂E_(i)E₄ AlkLE_(v)E_(vi) E_(b) 982 E_(1b)E₂E_(i)E₄ AlkLE_(v)E_(vi) E_(b) 983 E_(1a)E₂E_(ii)E₄ AlkLE_(v)E_(vi) E_(b) 984 E_(1b)E₂E_(ii)E₄ AlkLE_(v)E_(vi) E_(b) 985 E_(1a)E₂E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E_(b) 986 E_(1b)E₂E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E_(b) 987 E_(1a)E₂E₃E_(i)E₄ AlkLE_(v)E_(vi) E_(b) 988 E_(1b)E₂E₃E_(i)E₄ AlkLE_(v)E_(vi) E_(b) 989 E_(1a)E₂E₃E_(ii)E₄ AlkLE_(v)E_(vi) E_(b) 990 E_(1b)E₂E₃E_(ii)E₄ AlkLE_(v)E_(vi) E_(b) 991 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E_(b) 992 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E_(b) 993 E_(1a)E₂E_(iii) AlkLE_(v)E_(vi) E_(b) 994 E_(1b)E₂E_(iii) AlkLE_(v)E_(vi) E_(b) 995 E_(1a)E₂E₃E_(iii) AlkLE_(v)E_(vi) E_(b) 996 E_(1b)E₂E₃E_(iii) AlkLE_(v)E_(vi) E_(b) 997 E_(1a)E₂E_(iii)E₄ AlkLE_(v)E_(vi) E_(b) 998 E_(1b)E₂E_(iii)E₄ AlkLE_(v)E_(vi) E_(b) 999 E_(1a)E₂E₃E_(iii)E₄ AlkLE_(v)E_(vi) E_(b) 1000 E_(1b)E₂E₃E_(iii)E₄ AlkLE_(v)E_(vi) E_(b) 1001 E_(1a)E₂E_(iv) AlkLE_(v)E_(vi) E_(b) 1002 E_(1b)E₂E_(iv) AlkLE_(v)E_(vi) E_(b) 1003 E_(1a)E₂E₃E_(iv) AlkLE_(v)E_(vi) E_(b) 1004 E_(1b)E₂E₃E_(iv) AlkLE_(v)E_(vi) E_(b) 1005 E_(1a)E₂E_(iv)E₄ AlkLE_(v)E_(vi) E_(b) 1006 E_(1b)E₂E_(iv)E₄ AlkLE_(v)E_(vi) E_(b) 1007 E_(1a)E₂E₃E_(iv)E₄ AlkLE_(v)E_(vi) E_(b) 1008 E_(1b)E₂E₃E_(iv)E₄ AlkLE_(v)E_(vi) E_(b) 1009 E_(1a)E₂ AlkLE_(v)E_(vi) E₄* E_(b) 1010 E_(1b)E₂ AlkLE_(v)E_(vi) E₄* E_(b) 1011 E_(1a)E₂E₃ AlkLE_(v)E_(vi) E₄* E_(b) 1012 E_(1b)E₂E₃ AlkLE_(v)E_(vi) E₄* E_(b) 1013 E_(1a)E₂E_(i) AlkLE_(v)E_(vi) E₄* E_(b) 1014 E_(1b)E₂E_(i) AlkLE_(v)E_(vi) E₄* E_(b) 1015 E_(1a)E₂E_(ii) AlkLE_(v)E_(vi) E₄* E_(b) 1016 E_(1b)E₂E_(ii) AlkLE_(v)E_(vi) E₄* E_(b) 1017 E_(1a)E₂E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* E_(b) 1018 E_(1b)E₂E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* E_(b) 1019 E_(1a)E₂E₃E_(i) AlkLE_(v)E_(vi) E₄* E_(b) 1020 E_(1b)E₂E₃E_(i) AlkLE_(v)E_(vi) E₄* E_(b) 1021 E_(1a)E₂E₃E_(ii) AlkLE_(v)E_(vi) E₄* E_(b) 1022 E_(1b)E₂E₃E_(ii) AlkLE_(v)E_(vi) E₄* E_(b) 1023 E_(1a)E₂E₃E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* E_(b) 1024 E_(1b)E₂E₃E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* E_(b) 1025 E_(1a)E₂E₄ AlkLE_(v)E_(vi) E₄* E_(b) 1026 E_(1b)E₂E₄ AlkLE_(v)E_(vi) E₄* E_(b) 1027 E_(1a)E₂E₃E₄ AlkLE_(v)E_(vi) E₄* E_(b) 1028 E_(1b)E₂E₃E₄ AlkLE_(v)E_(vi) E₄* E_(b) 1029 E_(1a)E₂E_(i)E₄ AlkLE_(v)E_(vi) E₄* E_(b) 1030 E_(1b)E₂E_(i)E₄ AlkLE_(v)E_(vi) E₄* E_(b) 1031 E_(1a)E₂E_(ii)E₄ AlkLE_(v)E_(vi) E₄* E_(b) 1032 E_(1b)E₂E_(ii)E₄ AlkLE_(v)E_(vi) E₄* E_(b) 1033 E_(1a)E₂E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* E_(b) 1034 E_(1b)E₂E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* E_(b) 1035 E_(1a)E₂E₃E_(i)E₄ AlkLE_(v)E_(vi) E₄* E_(b) 1036 E_(1b)E₂E₃E_(i)E₄ AlkLE_(v)E_(vi) E₄* E_(b) 1037 E_(1a)E₂E₃E_(ii)E₄ AlkLE_(v)E_(vi) E₄* E_(b) 1038 E_(1b)E₂E₃E_(ii)E₄ AlkLE_(v)E_(vi) E₄* E_(b) 1039 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* E_(b) 1040 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* E_(b) 1041 E_(1a)E₂E_(iii) AlkLE_(v)E_(vi) E₄* E_(b) 1042 E_(1b)E₂E_(iii) AlkLE_(v)E_(vi) E₄* E_(b) 1043 E_(1a)E₂E₃E_(iii) AlkLE_(v)E_(vi) E₄* E_(b) 1044 E_(1b)E₂E₃E_(iii) AlkLE_(v)E_(vi) E₄* E_(b) 1045 E_(1a)E₂E_(iii)E₄ AlkLE_(v)E_(vi) E₄* E_(b) 1046 E_(1b)E₂E_(iii)E₄ AlkLE_(v)E_(vi) E₄* E_(b) 1047 E_(1a)E₂E₃E_(iii)E₄ AlkLE_(v)E_(vi) E₄* E_(b) 1048 E_(1b)E₂E₃E_(iii)E₄ AlkLE_(v)E_(vi) E₄* E_(b) 1049 E_(1a)E₂E_(iv) AlkLE_(v)E_(vi) E₄* E_(b) 1050 E_(1b)E₂E_(iv) AlkLE_(v)E_(vi) E₄* E_(b) 1051 E_(1a)E₂E₃E_(iv) AlkLE_(v)E_(vi) E₄* E_(b) 1052 E_(1b)E₂E₃E_(iv) AlkLE_(v)E_(vi) E₄* E_(b) 1053 E_(1a)E₂E_(iv)E₄ AlkLE_(v)E_(vi) E₄* E_(b) 1054 E_(1b)E₂E_(iv)E₄ AlkLE_(v)E_(vi) E₄* E_(b) 1055 E_(1a)E₂E₃E_(iv)E₄ AlkLE_(v)E_(vi) E₄* E_(b) 1056 E_(1b)E₂E₃E_(iv)E₄ AlkLE_(v)E_(vi) E₄* E_(b) 1057 E_(1a)E₂ AlkLE_(v)E_(vi) E₅ E_(b) 1058 E_(1b)E₂ AlkLE_(v)E_(vi) E₅ E_(b) 1059 E_(1a)E₂E₃ AlkLE_(v)E_(vi) E₅ E_(b) 1060 E_(1b)E₂E₃ AlkLE_(v)E_(vi) E₅ E_(b) 1061 E_(1a)E₂E_(i) AlkLE_(v)E_(vi) E₅ E_(b) 1062 E_(1b)E₂E_(i) AlkLE_(v)E_(vi) E₅ E_(b) 1063 E_(1a)E₂E_(ii) AlkLE_(v)E_(vi) E₅ E_(b) 1064 E_(1b)E₂E_(ii) AlkLE_(v)E_(vi) E₅ E_(b) 1065 E_(1a)E₂E_(ii)E_(iib) AlkLE_(v)E_(vi) E₅ E_(b) 1066 E_(1b)E₂E_(ii)E_(iib) AlkLE_(v)E_(vi) E₅ E_(b) 1067 E_(1a)E₂E₃E_(i) AlkLE_(v)E_(vi) E₅ E_(b) 1068 E_(1b)E₂E₃E_(i) AlkLE_(v)E_(vi) E₅ E_(b) 1069 E_(1a)E₂E₃E_(ii) AlkLE_(v)E_(vi) E₅ E_(b) 1070 E_(1b)E₂E₃E_(ii) AlkLE_(v)E_(vi) E₅ E_(b) 1071 E_(1a)E₂E₃E_(ii)E_(iib) AlkLE_(v)E_(vi) E₅ E_(b) 1072 E_(1b)E₂E₃E_(ii)E_(iib) AlkLE_(v)E_(vi) E₅ E_(b) 1073 E_(1a)E₂E₄ AlkLE_(v)E_(vi) E₅ E_(b) 1074 E_(1b)E₂E₄ AlkLE_(v)E_(vi) E₅ E_(b) 1075 E_(1a)E₂E₃E₄ AlkLE_(v)E_(vi) E₅ E_(b) 1076 E_(1b)E₂E₃E₄ AlkLE_(v)E_(vi) E₅ E_(b) 1077 E_(1a)E₂E_(i)E₄ AlkLE_(v)E_(vi) E₅ E_(b) 1078 E_(1b)E₂E_(i)E₄ AlkLE_(v)E_(vi) E₅ E_(b) 1079 E_(1a)E₂E_(ii)E₄ AlkLE_(v)E_(vi) E₅ E_(b) 1080 E_(1b)E₂E_(ii)E₄ AlkLE_(v)E_(vi) E₅ E_(b) 1081 E_(1a)E₂E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₅ E_(b) 1082 E_(1b)E₂E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₅ E_(b) 1083 E_(1a)E₂E₃E_(i)E₄ AlkLE_(v)E_(vi) E₅ E_(b) 1084 E_(1b)E₂E₃E_(i)E₄ AlkLE_(v)E_(vi) E₅ E_(b) 1085 E_(1a)E₂E₃E_(ii)E₄ AlkLE_(v)E_(vi) E₅ E_(b) 1086 E_(1b)E₂E₃E_(ii)E₄ AlkLE_(v)E_(vi) E₅ E_(b) 1087 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₅ E_(b) 1088 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₅ E_(b) 1089 E_(1a)E₂E_(iii) AlkLE_(v)E_(vi) E₅ E_(b) 1090 E_(1b)E₂E_(iii) AlkLE_(v)E_(vi) E₅ E_(b) 1091 E_(1a)E₂E₃E_(iii) AlkLE_(v)E_(vi) E₅ E_(b) 1092 E_(1b)E₂E₃E_(iii) AlkLE_(v)E_(vi) E₅ E_(b) 1093 E_(1a)E₂E_(iii)E₄ AlkLE_(v)E_(vi) E₅ E_(b) 1094 E_(1b)E₂E_(iii)E₄ AlkLE_(v)E_(vi) E₅ E_(b) 1095 E_(1a)E₂E₃E_(iii)E₄ AlkLE_(v)E_(vi) E₅ E_(b) 1096 E_(1b)E₂E₃E_(iii)E₄ AlkLE_(v)E_(vi) E₅ E_(b) 1097 E_(1a)E₂E_(iv) AlkLE_(v)E_(vi) E₅ E_(b) 1098 E_(1b)E₂E_(iv) AlkLE_(v)E_(vi) E₅ E_(b) 1099 E_(1a)E₂E₃E_(iv) AlkLE_(v)E_(vi) E₅ E_(b) 1100 E_(1b)E₂E₃E_(iv) AlkLE_(v)E_(vi) E₅ E_(b) 1101 E_(1a)E₂E_(iv)E₄ AlkLE_(v)E_(vi) E₅ E_(b) 1102 E_(1b)E₂E_(iv)E₄ AlkLE_(v)E_(vi) E₅ E_(b) 1103 E_(1a)E₂E₃E_(iv)E₄ AlkLE_(v)E_(vi) E₅ E_(b) 1104 E_(1b)E₂E₃E_(iv)E₄ AlkLE_(v)E_(vi) E₅ E_(b) 1105 E_(1a)E₂ AlkLE_(v)E_(vi) E₄*E₅ E_(b) 1106 E_(1b)E₂ AlkLE_(v)E_(vi) E₄*E₅ E_(b) 1107 E_(1a)E₂E₃ AlkLE_(v)E_(vi) E₄*E₅ E_(b) 1108 E_(1b)E₂E₃ AlkLE_(v)E_(vi) E₄*E₅ E_(b) 1109 E_(1a)E₂E_(i) AlkLE_(v)E_(vi) E₄*E₅ E_(b) 1110 E_(1b)E₂E_(i) AlkLE_(v)E_(vi) E₄*E₅ E_(b) 1111 E_(1a)E₂E_(ii) AlkLE_(v)E_(vi) E₄*E₅ E_(b) 1112 E_(1b)E₂E_(ii) AlkLE_(v)E_(vi) E₄*E₅ E_(b) 1113 E_(1a)E₂E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄*E₅ E_(b) 1114 E_(1b)E₂E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄*E₅ E_(b) 1115 E_(1a)E₂E₃E_(i) AlkLE_(v)E_(vi) E₄*E₅ E_(b) 1116 E_(1b)E₂E₃E_(i) AlkLE_(v)E_(vi) E₄*E₅ E_(b) 1117 E_(1a)E₂E₃E_(ii) AlkLE_(v)E_(vi) E₄*E₅ E_(b) 1118 E_(1b)E₂E₃E_(ii) AlkLE_(v)E_(vi) E₄*E₅ E_(b) 1119 E_(1a)E₂E₃E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄*E₅ E_(b) 1120 E_(1b)E₂E₃E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄*E₅ E_(b) 1121 E_(1a)E₂E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(b) 1122 E_(1b)E₂E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(b) 1123 E_(1a)E₂E₃E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(b) 1124 E_(1b)E₂E₃E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(b) 1125 E_(1a)E₂E_(i)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(b) 1126 E_(1b)E₂E_(i)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(b) 1127 E_(1a)E₂E_(ii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(b) 1128 E_(1b)E₂E_(ii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(b) 1129 E_(1a)E₂E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(b) 1130 E_(1b)E₂E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(b) 1131 E_(1a)E₂E₃E_(i)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(b) 1132 E_(1b)E₂E₃E_(i)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(b) 1133 E_(1a)E₂E₃E_(ii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(b) 1134 E_(1b)E₂E₃E_(ii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(b) 1135 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(b) 1136 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(b) 1137 E_(1a)E₂E_(iii) AlkLE_(v)E_(vi) E₄*E₅ E_(b) 1138 E_(1b)E₂E_(iii) AlkLE_(v)E_(vi) E₄*E₅ E_(b) 1139 E_(1a)E₂E₃E_(iii) AlkLE_(v)E_(vi) E₄*E₅ E_(b) 1140 E_(1b)E₂E₃E_(iii) AlkLE_(v)E_(vi) E₄*E₅ E_(b) 1141 E_(1a)E₂E_(iii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(b) 1142 E_(1b)E₂E_(iii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(b) 1143 E_(1a)E₂E₃E_(iii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(b) 1144 E_(1b)E₂E₃E_(iii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(b) 1145 E_(1a)E₂E_(iv) AlkLE_(v)E_(vi) E₄*E₅ E_(b) 1146 E_(1b)E₂E_(iv) AlkLE_(v)E_(vi) E₄*E₅ E_(b) 1147 E_(1a)E₂E₃E_(iv) AlkLE_(v)E_(vi) E₄*E₅ E_(b) 1148 E_(1b)E₂E₃E_(iv) AlkLE_(v)E_(vi) E₄*E₅ E_(b) 1149 E_(1a)E₂E_(iv)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(b) 1150 E_(1b)E₂E_(iv)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(b) 1151 E_(1a)E₂E₃E_(iv)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(b) 1152 E_(1b)E₂E₃E_(iv)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(b) 1153 E_(1a)E₂ E_(v)E_(vi) E_(d) 1154 E_(1b)E₂ E_(v)E_(vi) E_(d) 1155 E_(1a)E₂E₃ E_(v)E_(vi) E_(d) 1156 E_(1b)E₂E₃ E_(v)E_(vi) E_(d) 1157 E_(1a)E₂E_(i) E_(v)E_(vi) E_(d) 1158 E_(1b)E₂E_(i) E_(v)E_(vi) E_(d) 1159 E_(1a)E₂E_(ii) E_(v)E_(vi) E_(d) 1160 E_(1b)E₂E_(ii) E_(v)E_(vi) E_(d) 1161 E_(1a)E₂E_(ii)E_(iib) E_(v)E_(vi) E_(d) 1162 E_(1b)E₂E_(ii)E_(iib) E_(v)E_(vi) E_(d) 1163 E_(1a)E₂E₃E_(i) E_(v)E_(vi) E_(d) 1164 E_(1b)E₂E₃E_(i) E_(v)E_(vi) E_(d) 1165 E_(1a)E₂E₃E_(ii) E_(v)E_(vi) E_(d) 1166 E_(1b)E₂E₃E_(ii) E_(v)E_(vi) E_(d) 1167 E_(1a)E₂E₃E_(ii)E_(iib) E_(v)E_(vi) E_(d) 1168 E_(1b)E₂E₃E_(ii)E_(iib) E_(v)E_(vi) E_(d) 1169 E_(1a)E₂E₄ E_(v)E_(vi) E_(d) 1170 E_(1b)E₂E₄ E_(v)E_(vi) E_(d) 1171 E_(1a)E₂E₃E₄ E_(v)E_(vi) E_(d) 1172 E_(1b)E₂E₃E₄ E_(v)E_(vi) E_(d) 1173 E_(1a)E₂E_(i)E₄ E_(v)E_(vi) E_(d) 1174 E_(1b)E₂E_(i)E₄ E_(v)E_(vi) E_(d) 1175 E_(1a)E₂E_(ii)E₄ E_(v)E_(vi) E_(d) 1176 E_(1b)E₂E_(ii)E₄ E_(v)E_(vi) E_(d) 1177 E_(1a)E₂E_(ii)E_(iib)E₄ E_(v)E_(vi) E_(d) 1178 E_(1b)E₂E_(ii)E_(iib)E₄ E_(v)E_(vi) E_(d) 1179 E_(1a)E₂E₃E_(i)E₄ E_(v)E_(vi) E_(d) 1180 E_(1b)E₂E₃E_(i)E₄ E_(v)E_(vi) E_(d) 1181 E_(1a)E₂E₃E_(ii)E₄ E_(v)E_(vi) E_(d) 1182 E_(1b)E₂E₃E_(ii)E₄ E_(v)E_(vi) E_(d) 1183 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E_(v)E_(vi) E_(d) 1184 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E_(v)E_(vi) E_(d) 1185 E_(1a)E₂E_(iii) E_(v)E_(vi) E_(d) 1186 E_(1b)E₂E_(iii) E_(v)E_(vi) E_(d) 1187 E_(1a)E₂E₃E_(iii) E_(v)E_(vi) E_(d) 1188 E_(1b)E₂E₃E_(iii) E_(v)E_(vi) E_(d) 1189 E_(1a)E₂E_(iii)E₄ E_(v)E_(vi) E_(d) 1190 E_(1b)E₂E_(iii)E₄ E_(v)E_(vi) E_(d) 1191 E_(1a)E₂E₃E_(iii)E₄ E_(v)E_(vi) E_(d) 1192 E_(1b)E₂E₃E_(iii)E₄ E_(v)E_(vi) E_(d) 1193 E_(1a)E₂E_(iv) E_(v)E_(vi) E_(d) 1194 E_(1b)E₂E_(iv) E_(v)E_(vi) E_(d) 1195 E_(1a)E₂E₃E_(iv) E_(v)E_(vi) E_(d) 1196 E_(1b)E₂E₃E_(iv) E_(v)E_(vi) E_(d) 1197 E_(1a)E₂E_(iv)E₄ E_(v)E_(vi) E_(d) 1198 E_(1b)E₂E_(iv)E₄ E_(v)E_(vi) E_(d) 1199 E_(1a)E₂E₃E_(iv)E₄ E_(v)E_(vi) E_(d) 1200 E_(1b)E₂E₃E_(iv)E₄ E_(v)E_(vi) E_(d) 1201 E_(1a)E₂ E_(v)E_(vi) E₄* E_(d) 1202 E_(1b)E₂ E_(v)E_(vi) E₄* E_(d) 1203 E_(1a)E₂E₃ E_(v)E_(vi) E₄* E_(d) 1204 E_(1b)E₂E₃ E_(v)E_(vi) E₄* E_(d) 1205 E_(1a)E₂E_(i) E_(v)E_(vi) E₄* E_(d) 1206 E_(1b)E₂E_(i) E_(v)E_(vi) E₄* E_(d) 1207 E_(1a)E₂E_(ii) E_(v)E_(vi) E₄* E_(d) 1208 E_(1b)E₂E_(ii) E_(v)E_(vi) E₄* E_(d) 1209 E_(1a)E₂E_(ii)E_(iib) E_(v)E_(vi) E₄* E_(d) 1210 E_(1b)E₂E_(ii)E_(iib) E_(v)E_(vi) E₄* E_(d) 1211 E_(1a)E₂E₃E_(i) E_(v)E_(vi) E₄* E_(d) 1212 E_(1b)E₂E₃E_(i) E_(v)E_(vi) E₄* E_(d) 1213 E_(1a)E₂E₃E_(ii) E_(v)E_(vi) E₄* E_(d) 1214 E_(1b)E₂E₃E_(ii) E_(v)E_(vi) E₄* E_(d) 1215 E_(1a)E₂E₃E_(ii)E_(iib) E_(v)E_(vi) E₄* E_(d) 1216 E_(1b)E₂E₃E_(ii)E_(iib) E_(v)E_(vi) E₄* E_(d) 1217 E_(1a)E₂E₄ E_(v)E_(vi) E₄* E_(d) 1218 E_(1b)E₂E₄ E_(v)E_(vi) E₄* E_(d) 1219 E_(1a)E₂E₃E₄ E_(v)E_(vi) E₄* E_(d) 1220 E_(1b)E₂E₃E₄ E_(v)E_(vi) E₄* E_(d) 1221 E_(1a)E₂E_(i)E₄ E_(v)E_(vi) E₄* E_(d) 1222 E_(1b)E₂E_(i)E₄ E_(v)E_(vi) E₄* E_(d) 1223 E_(1a)E₂E_(ii)E₄ E_(v)E_(vi) E₄* E_(d) 1224 E_(1b)E₂E_(ii)E₄ E_(v)E_(vi) E₄* E_(d) 1225 E_(1a)E₂E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* E_(d) 1226 E_(1b)E₂E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* E_(d) 1227 E_(1a)E₂E₃E_(i)E₄ E_(v)E_(vi) E₄* E_(d) 1228 E_(1b)E₂E₃E_(i)E₄ E_(v)E_(vi) E₄* E_(d) 1229 E_(1a)E₂E₃E_(ii)E₄ E_(v)E_(vi) E₄* E_(d) 1230 E_(1b)E₂E₃E_(ii)E₄ E_(v)E_(vi) E₄* E_(d) 1231 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* E_(d) 1232 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* E_(d) 1233 E_(1a)E₂E_(iii) E_(v)E_(vi) E₄* E_(d) 1234 E_(1b)E₂E_(iii) E_(v)E_(vi) E₄* E_(d) 1235 E_(1a)E₂E₃E_(iii) E_(v)E_(vi) E₄* E_(d) 1236 E_(1b)E₂E₃E_(iii) E_(v)E_(vi) E₄* E_(d) 1237 E_(1a)E₂E_(iii)E₄ E_(v)E_(vi) E₄* E_(d) 1238 E_(1b)E₂E_(iii)E₄ E_(v)E_(vi) E₄* E_(d) 1239 E_(1a)E₂E₃E_(iii)E₄ E_(v)E_(vi) E₄* E_(d) 1240 E_(1b)E₂E₃E_(iii)E₄ E_(v)E_(vi) E₄* E_(d) 1241 E_(1a)E₂E_(iv) E_(v)E_(vi) E₄* E_(d) 1242 E_(1b)E₂E_(iv) E_(v)E_(vi) E₄* E_(d) 1243 E_(1a)E₂E₃E_(iv) E_(v)E_(vi) E₄* E_(d) 1244 E_(1b)E₂E₃E_(iv) E_(v)E_(vi) E₄* E_(d) 1245 E_(1a)E₂E_(iv)E₄ E_(v)E_(vi) E₄* E_(d) 1246 E_(1b)E₂E_(iv)E₄ E_(v)E_(vi) E₄* E_(d) 1247 E_(1a)E₂E₃E_(iv)E₄ E_(v)E_(vi) E₄* E_(d) 1248 E_(1b)E₂E₃E_(iv)E₄ E_(v)E_(vi) E₄* E_(d) 1249 E_(1a)E₂ E_(v)E_(vi) E₅ E_(d) 1250 E_(1b)E₂ E_(v)E_(vi) E₅ E_(d) 1251 E_(1a)E₂E₃ E_(v)E_(vi) E₅ E_(d) 1252 E_(1b)E₂E₃ E_(v)E_(vi) E₅ E_(d) 1253 E_(1a)E₂E_(i) E_(v)E_(vi) E₅ E_(d) 1254 E_(1b)E₂E_(i) E_(v)E_(vi) E₅ E_(d) 1255 E_(1a)E₂E_(ii) E_(v)E_(vi) E₅ E_(d) 1256 E_(1b)E₂E_(ii) E_(v)E_(vi) E₅ E_(d) 1257 E_(1a)E₂E_(ii)E_(iib) E_(v)E_(vi) E₅ E_(d) 1258 E_(1b)E₂E_(ii)E_(iib) E_(v)E_(vi) E₅ E_(d) 1259 E_(1a)E₂E₃E_(i) E_(v)E_(vi) E₅ E_(d) 1260 E_(1b)E₂E₃E_(i) E_(v)E_(vi) E₅ E_(d) 1261 E_(1a)E₂E₃E_(ii) E_(v)E_(vi) E₅ E_(d) 1262 E_(1b)E₂E₃E_(ii) E_(v)E_(vi) E₅ E_(d) 1263 E_(1a)E₂E₃E_(ii)E_(iib) E_(v)E_(vi) E₅ E_(d) 1264 E_(1b)E₂E₃E_(ii)E_(iib) E_(v)E_(vi) E₅ E_(d) 1265 E_(1a)E₂E₄ E_(v)E_(vi) E₅ E_(d) 1266 E_(1b)E₂E₄ E_(v)E_(vi) E₅ E_(d) 1267 E_(1a)E₂E₃E₄ E_(v)E_(vi) E₅ E_(d) 1268 E_(1b)E₂E₃E₄ E_(v)E_(vi) E₅ E_(d) 1269 E_(1a)E₂E_(i)E₄ E_(v)E_(vi) E₅ E_(d) 1270 E_(1b)E₂E_(i)E₄ E_(v)E_(vi) E₅ E_(d) 1271 E_(1a)E₂E_(ii)E₄ E_(v)E_(vi) E₅ E_(d) 1272 E_(1b)E₂E_(ii)E₄ E_(v)E_(vi) E₅ E_(d) 1273 E_(1a)E₂E_(ii)E_(iib)E₄ E_(v)E_(vi) E₅ E_(d) 1274 E_(1b)E₂E_(ii)E_(iib)E₄ E_(v)E_(vi) E₅ E_(d) 1275 E_(1a)E₂E₃E_(i)E₄ E_(v)E_(vi) E₅ E_(d) 1276 E_(1b)E₂E₃E_(i)E₄ E_(v)E_(vi) E₅ E_(d) 1277 E_(1a)E₂E₃E_(ii)E₄ E_(v)E_(vi) E₅ E_(d) 1278 E_(1b)E₂E₃E_(ii)E₄ E_(v)E_(vi) E₅ E_(d) 1279 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E_(v)E_(vi) E₅ E_(d) 1280 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E_(v)E_(vi) E₅ E_(d) 1281 E_(1a)E₂E_(iii) E_(v)E_(vi) E₅ E_(d) 1282 E_(1b)E₂E_(iii) E_(v)E_(vi) E₅ E_(d) 1283 E_(1a)E₂E₃E_(iii) E_(v)E_(vi) E₅ E_(d) 1284 E_(1b)E₂E₃E_(iii) E_(v)E_(vi) E₅ E_(d) 1285 E_(1a)E₂E_(iii)E₄ E_(v)E_(vi) E₅ E_(d) 1286 E_(1b)E₂E_(iii)E₄ E_(v)E_(vi) E₅ E_(d) 1287 E_(1a)E₂E₃E_(iii)E₄ E_(v)E_(vi) E₅ E_(d) 1288 E_(1b)E₂E₃E_(iii)E₄ E_(v)E_(vi) E₅ E_(d) 1289 E_(1a)E₂E_(iv) E_(v)E_(vi) E₅ E_(d) 1290 E_(1b)E₂E_(iv) E_(v)E_(vi) E₅ E_(d) 1291 E_(1a)E₂E₃E_(iv) E_(v)E_(vi) E₅ E_(d) 1292 E_(1b)E₂E₃E_(iv) E_(v)E_(vi) E₅ E_(d) 1293 E_(1a)E₂E_(iv)E₄ E_(v)E_(vi) E₅ E_(d) 1294 E_(1b)E₂E_(iv)E₄ E_(v)E_(vi) E₅ E_(d) 1295 E_(1a)E₂E₃E_(iv)E₄ E_(v)E_(vi) E₅ E_(d) 1296 E_(1b)E₂E₃E_(iv)E₄ E_(v)E_(vi) E₅ E_(d) 1297 E_(1a)E₂ E_(v)E_(vi) E₄*E₅ E_(d) 1298 E_(1b)E₂ E_(v)E_(vi) E₄*E₅ E_(d) 1299 E_(1a)E₂E₃ E_(v)E_(vi) E₄*E₅ E_(d) 1300 E_(1b)E₂E₃ E_(v)E_(vi) E₄*E₅ E_(d) 1301 E_(1a)E₂E_(i) E_(v)E_(vi) E₄*E₅ E_(d) 1302 E_(1b)E₂E_(i) E_(v)E_(vi) E₄*E₅ E_(d) 1303 E_(1a)E₂E_(ii) E_(v)E_(vi) E₄*E₅ E_(d) 1304 E_(1b)E₂E_(ii) E_(v)E_(vi) E₄*E₅ E_(d) 1305 E_(1a)E₂E_(ii)E_(iib) E_(v)E_(vi) E₄*E₅ E_(d) 1306 E_(1b)E₂E_(ii)E_(iib) E_(v)E_(vi) E₄*E₅ E_(d) 1307 E_(1a)E₂E₃E_(i) E_(v)E_(vi) E₄*E₅ E_(d) 1308 E_(1b)E₂E₃E_(i) E_(v)E_(vi) E₄*E₅ E_(d) 1309 E_(1a)E₂E₃E_(ii) E_(v)E_(vi) E₄*E₅ E_(d) 1310 E_(1b)E₂E₃E_(ii) E_(v)E_(vi) E₄*E₅ E_(d) 1311 E_(1a)E₂E₃E_(ii)E_(iib) E_(v)E_(vi) E₄*E₅ E_(d) 1312 E_(1b)E₂E₃E_(ii)E_(iib) E_(v)E_(vi) E₄*E₅ E_(d) 1313 E_(1a)E₂E₄ E_(v)E_(vi) E₄*E₅ E_(d) 1314 E_(1b)E₂E₄ E_(v)E_(vi) E₄*E₅ E_(d) 1315 E_(1a)E₂E₃E₄ E_(v)E_(vi) E₄*E₅ E_(d) 1316 E_(1b)E₂E₃E₄ E_(v)E_(vi) E₄*E₅ E_(d) 1317 E_(1a)E₂E_(i)E₄ E_(v)E_(vi) E₄*E₅ E_(d) 1318 E_(1b)E₂E_(i)E₄ E_(v)E_(vi) E₄*E₅ E_(d) 1319 E_(1a)E₂E_(ii)E₄ E_(v)E_(vi) E₄*E₅ E_(d) 1320 E_(1b)E₂E_(ii)E₄ E_(v)E_(vi) E₄*E₅ E_(d) 1321 E_(1a)E₂E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄*E₅ E_(d) 1322 E_(1b)E₂E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄*E₅ E_(d) 1323 E_(1a)E₂E₃E_(i)E₄ E_(v)E_(vi) E₄*E₅ E_(d) 1324 E_(1b)E₂E₃E_(i)E₄ E_(v)E_(vi) E₄*E₅ E_(d) 1325 E_(1a)E₂E₃E_(ii)E₄ E_(v)E_(vi) E₄*E₅ E_(d) 1326 E_(1b)E₂E₃E_(ii)E₄ E_(v)E_(vi) E₄*E₅ E_(d) 1327 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄*E₅ E_(d) 1328 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄*E₅ E_(d) 1329 E_(1a)E₂E_(iii) E_(v)E_(vi) E₄*E₅ E_(d) 1330 E_(1b)E₂E_(iii) E_(v)E_(vi) E₄*E₅ E_(d) 1331 E_(1a)E₂E₃E_(iii) E_(v)E_(vi) E₄*E₅ E_(d) 1332 E_(1b)E₂E₃E_(iii) E_(v)E_(vi) E₄*E₅ E_(d) 1333 E_(1a)E₂E_(iii)E₄ E_(v)E_(vi) E₄*E₅ E_(d) 1334 E_(1b)E₂E_(iii)E₄ E_(v)E_(vi) E₄*E₅ E_(d) 1335 E_(1a)E₂E₃E_(iii)E₄ E_(v)E_(vi) E₄*E₅ E_(d) 1336 E_(1b)E₂E₃E_(iii)E₄ E_(v)E_(vi) E₄*E₅ E_(d) 1337 E_(1a)E₂E_(iv) E_(v)E_(vi) E₄*E₅ E_(d) 1338 E_(1b)E₂E_(iv) E_(v)E_(vi) E₄*E₅ E_(d) 1339 E_(1a)E₂E₃E_(iv) E_(v)E_(vi) E₄*E₅ E_(d) 1340 E_(1b)E₂E₃E_(iv) E_(v)E_(vi) E₄*E₅ E_(d) 1341 E_(1a)E₂E_(iv)E₄ E_(v)E_(vi) E₄*E₅ E_(d) 1342 E_(1b)E₂E_(iv)E₄ E_(v)E_(vi) E₄*E₅ E_(d) 1343 E_(1a)E₂E₃E_(iv)E₄ E_(v)E_(vi) E₄*E₅ E_(d) 1344 E_(1b)E₂E₃E_(iv)E₄ E_(v)E_(vi) E₄*E₅ E_(d) 1345 E_(1a)E₂ AlkLE_(v)E_(vi) E_(d) 1346 E_(1b)E₂ AlkLE_(v)E_(vi) E_(d) 1347 E_(1a)E₂E₃ AlkLE_(v)E_(vi) E_(d) 1348 E_(1b)E₂E₃ AlkLE_(v)E_(vi) E_(d) 1349 E_(1a)E₂E_(i) AlkLE_(v)E_(vi) E_(d) 1350 E_(1b)E₂E_(i) AlkLE_(v)E_(vi) E_(d) 1351 E_(1a)E₂E_(ii) AlkLE_(v)E_(vi) E_(d) 1352 E_(1b)E₂E_(ii) AlkLE_(v)E_(vi) E_(d) 1353 E_(1a)E₂E_(ii)E_(iib) AlkLE_(v)E_(vi) E_(d) 1354 E_(1b)E₂E_(ii)E_(iib) AlkLE_(v)E_(vi) E_(d) 1355 E_(1a)E₂E₃E_(i) AlkLE_(v)E_(vi) E_(d) 1356 E_(1b)E₂E₃E_(i) AlkLE_(v)E_(vi) E_(d) 1357 E_(1a)E₂E₃E_(ii) AlkLE_(v)E_(vi) E_(d) 1358 E_(1b)E₂E₃E_(ii) AlkLE_(v)E_(vi) E_(d) 1359 E_(1a)E₂E₃E_(ii)E_(iib) AlkLE_(v)E_(vi) E_(d) 1360 E_(1b)E₂E₃E_(ii)E_(iib) AlkLE_(v)E_(vi) E_(d) 1361 E_(1a)E₂E₄ AlkLE_(v)E_(vi) E_(d) 1362 E_(1b)E₂E₄ AlkLE_(v)E_(vi) E_(d) 1363 E_(1a)E₂E₃E₄ AlkLE_(v)E_(vi) E_(d) 1364 E_(1b)E₂E₃E₄ AlkLE_(v)E_(vi) E_(d) 1365 E_(1a)E₂E_(i)E₄ AlkLE_(v)E_(vi) E_(d) 1366 E_(1b)E₂E_(i)E₄ AlkLE_(v)E_(vi) E_(d) 1367 E_(1a)E₂E_(ii)E₄ AlkLE_(v)E_(vi) E_(d) 1368 E_(1b)E₂E_(ii)E₄ AlkLE_(v)E_(vi) E_(d) 1369 E_(1a)E₂E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E_(d) 1370 E_(1b)E₂E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E_(d) 1371 E_(1a)E₂E₃E_(i)E₄ AlkLE_(v)E_(vi) E_(d) 1372 E_(1b)E₂E₃E_(i)E₄ AlkLE_(v)E_(vi) E_(d) 1373 E_(1a)E₂E₃E_(ii)E₄ AlkLE_(v)E_(vi) E_(d) 1374 E_(1b)E₂E₃E_(ii)E₄ AlkLE_(v)E_(vi) E_(d) 1375 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E_(d) 1376 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E_(d) 1377 E_(1a)E₂E_(iii) AlkLE_(v)E_(vi) E_(d) 1378 E_(1b)E₂E_(iii) AlkLE_(v)E_(vi) E_(d) 1379 E_(1a)E₂E₃E_(iii) AlkLE_(v)E_(vi) E_(d) 1380 E_(1b)E₂E₃E_(iii) AlkLE_(v)E_(vi) E_(d) 1381 E_(1a)E₂E_(iii)E₄ AlkLE_(v)E_(vi) E_(d) 1382 E_(1b)E₂E_(iii)E₄ AlkLE_(v)E_(vi) E_(d) 1383 E_(1a)E₂E₃E_(iii)E₄ AlkLE_(v)E_(vi) E_(d) 1384 E_(1b)E₂E₃E_(iii)E₄ AlkLE_(v)E_(vi) E_(d) 1385 E_(1a)E₂E_(iv) AlkLE_(v)E_(vi) E_(d) 1386 E_(1b)E₂E_(iv) AlkLE_(v)E_(vi) E_(d) 1387 E_(1a)E₂E₃E_(iv) AlkLE_(v)E_(vi) E_(d) 1388 E_(1b)E₂E₃E_(iv) AlkLE_(v)E_(vi) E_(d) 1389 E_(1a)E₂E_(iv)E₄ AlkLE_(v)E_(vi) E_(d) 1390 E_(1b)E₂E_(iv)E₄ AlkLE_(v)E_(vi) E_(d) 1391 E_(1a)E₂E₃E_(iv)E₄ AlkLE_(v)E_(vi) E_(d) 1392 E_(1b)E₂E₃E_(iv)E₄ AlkLE_(v)E_(vi) E_(d) 1393 E_(1a)E₂ AlkLE_(v)E_(vi) E₄* E_(d) 1394 E_(1b)E₂ AlkLE_(v)E_(vi) E₄* E_(d) 1395 E_(1a)E₂E₃ AlkLE_(v)E_(vi) E₄* E_(d) 1396 E_(1b)E₂E₃ AlkLE_(v)E_(vi) E₄* E_(d) 1397 E_(1a)E₂E_(i) AlkLE_(v)E_(vi) E₄* E_(d) 1398 E_(1b)E₂E_(i) AlkLE_(v)E_(vi) E₄* E_(d) 1399 E_(1a)E₂E_(ii) AlkLE_(v)E_(vi) E₄* E_(d) 1400 E_(1b)E₂E_(ii) AlkLE_(v)E_(vi) E₄* E_(d) 1401 E_(1a)E₂E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* E_(d) 1402 E_(1b)E₂E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* E_(d) 1403 E_(1a)E₂E₃E_(i) AlkLE_(v)E_(vi) E₄* E_(d) 1404 E_(1b)E₂E₃E_(i) AlkLE_(v)E_(vi) E₄* E_(d) 1405 E_(1a)E₂E₃E_(ii) AlkLE_(v)E_(vi) E₄* E_(d) 1406 E_(1b)E₂E₃E_(ii) AlkLE_(v)E_(vi) E₄* E_(d) 1407 E_(1a)E₂E₃E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* E_(d) 1408 E_(1b)E₂E₃E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* E_(d) 1409 E_(1a)E₂E₄ AlkLE_(v)E_(vi) E₄* E_(d) 1410 E_(1b)E₂E₄ AlkLE_(v)E_(vi) E₄* E_(d) 1411 E_(1a)E₂E₃E₄ AlkLE_(v)E_(vi) E₄* E_(d) 1412 E_(1b)E₂E₃E₄ AlkLE_(v)E_(vi) E₄* E_(d) 1413 E_(1a)E₂E_(i)E₄ AlkLE_(v)E_(vi) E₄* E_(d) 1414 E_(1b)E₂E_(i)E₄ AlkLE_(v)E_(vi) E₄* E_(d) 1415 E_(1a)E₂E_(ii)E₄ AlkLE_(v)E_(vi) E₄* E_(d) 1416 E_(1b)E₂E_(ii)E₄ AlkLE_(v)E_(vi) E₄* E_(d) 1417 E_(1a)E₂E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* E_(d) 1418 E_(1b)E₂E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* E_(d) 1419 E_(1a)E₂E₃E_(i)E₄ AlkLE_(v)E_(vi) E₄* E_(d) 1420 E_(1b)E₂E₃E_(i)E₄ AlkLE_(v)E_(vi) E₄* E_(d) 1421 E_(1a)E₂E₃E_(ii)E₄ AlkLE_(v)E_(vi) E₄* E_(d) 1422 E_(1b)E₂E₃E_(ii)E₄ AlkLE_(v)E_(vi) E₄* E_(d) 1423 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* E_(d) 1424 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* E_(d) 1425 E_(1a)E₂E_(iii) AlkLE_(v)E_(vi) E₄* E_(d) 1426 E_(1b)E₂E_(iii) AlkLE_(v)E_(vi) E₄* E_(d) 1427 E_(1a)E₂E₃E_(iii) AlkLE_(v)E_(vi) E₄* E_(d) 1428 E_(1b)E₂E₃E_(iii) AlkLE_(v)E_(vi) E₄* E_(d) 1429 E_(1a)E₂E_(iii)E₄ AlkLE_(v)E_(vi) E₄* E_(d) 1430 E_(1b)E₂E_(iii)E₄ AlkLE_(v)E_(vi) E₄* E_(d) 1431 E_(1a)E₂E₃E_(iii)E₄ AlkLE_(v)E_(vi) E₄* E_(d) 1432 E_(1b)E₂E₃E_(iii)E₄ AlkLE_(v)E_(vi) E₄* E_(d) 1433 E_(1a)E₂E_(iv) AlkLE_(v)E_(vi) E₄* E_(d) 1434 E_(1b)E₂E_(iv) AlkLE_(v)E_(vi) E₄* E_(d) 1435 E_(1a)E₂E₃E_(iv) AlkLE_(v)E_(vi) E₄* E_(d) 1436 E_(1b)E₂E₃E_(iv) AlkLE_(v)E_(vi) E₄* E_(d) 1437 E_(1a)E₂E_(iv)E₄ AlkLE_(v)E_(vi) E₄* E_(d) 1438 E_(1b)E₂E_(iv)E₄ AlkLE_(v)E_(vi) E₄* E_(d) 1439 E_(1a)E₂E₃E_(iv)E₄ AlkLE_(v)E_(vi) E₄* E_(d) 1440 E_(1b)E₂E₃E_(iv)E₄ AlkLE_(v)E_(vi) E₄* E_(d) 1441 E_(1a)E₂ AlkLE_(v)E_(vi) E₅ E_(d) 1442 E_(1b)E₂ AlkLE_(v)E_(vi) E₅ E_(d) 1443 E_(1a)E₂E₃ AlkLE_(v)E_(vi) E₅ E_(d) 1444 E_(1b)E₂E₃ AlkLE_(v)E_(vi) E₅ E_(d) 1445 E_(1a)E₂E_(i) AlkLE_(v)E_(vi) E₅ E_(d) 1446 E_(1b)E₂E_(i) AlkLE_(v)E_(vi) E₅ E_(d) 1447 E_(1a)E₂E_(ii) AlkLE_(v)E_(vi) E₅ E_(d) 1448 E_(1b)E₂E_(ii) AlkLE_(v)E_(vi) E₅ E_(d) 1449 E_(1a)E₂E_(ii)E_(iib) AlkLE_(v)E_(vi) E₅ E_(d) 1450 E_(1b)E₂E_(ii)E_(iib) AlkLE_(v)E_(vi) E₅ E_(d) 1451 E_(1a)E₂E₃E_(i) AlkLE_(v)E_(vi) E₅ E_(d) 1452 E_(1b)E₂E₃E_(i) AlkLE_(v)E_(vi) E₅ E_(d) 1453 E_(1a)E₂E₃E_(ii) AlkLE_(v)E_(vi) E₅ E_(d) 1454 E_(1b)E₂E₃E_(ii) AlkLE_(v)E_(vi) E₅ E_(d) 1455 E_(1a)E₂E₃E_(ii)E_(iib) AlkLE_(v)E_(vi) E₅ E_(d) 1456 E_(1b)E₂E₃E_(ii)E_(iib) AlkLE_(v)E_(vi) E₅ E_(d) 1457 E_(1a)E₂E₄ AlkLE_(v)E_(vi) E₅ E_(d) 1458 E_(1b)E₂E₄ AlkLE_(v)E_(vi) E₅ E_(d) 1459 E_(1a)E₂E₃E₄ AlkLE_(v)E_(vi) E₅ E_(d) 1460 E_(1b)E₂E₃E₄ AlkLE_(v)E_(vi) E₅ E_(d) 1461 E_(1a)E₂E_(i)E₄ AlkLE_(v)E_(vi) E₅ E_(d) 1462 E_(1b)E₂E_(i)E₄ AlkLE_(v)E_(vi) E₅ E_(d) 1463 E_(1a)E₂E_(ii)E₄ AlkLE_(v)E_(vi) E₅ E_(d) 1464 E_(1b)E₂E_(ii)E₄ AlkLE_(v)E_(vi) E₅ E_(d) 1465 E_(1a)E₂E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₅ E_(d) 1466 E_(1b)E₂E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₅ E_(d) 1467 E_(1a)E₂E₃E_(i)E₄ AlkLE_(v)E_(vi) E₅ E_(d) 1468 E_(1b)E₂E₃E_(i)E₄ AlkLE_(v)E_(vi) E₅ E_(d) 1469 E_(1a)E₂E₃E_(ii)E₄ AlkLE_(v)E_(vi) E₅ E_(d) 1470 E_(1b)E₂E₃E_(ii)E₄ AlkLE_(v)E_(vi) E₅ E_(d) 1471 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₅ E_(d) 1472 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₅ E_(d) 1473 E_(1a)E₂E_(iii) AlkLE_(v)E_(vi) E₅ E_(d) 1474 E_(1b)E₂E_(iii) AlkLE_(v)E_(vi) E₅ E_(d) 1475 E_(1a)E₂E₃E_(iii) AlkLE_(v)E_(vi) E₅ E_(d) 1476 E_(1b)E₂E₃E_(iii) AlkLE_(v)E_(vi) E₅ E_(d) 1477 E_(1a)E₂E_(iii)E₄ AlkLE_(v)E_(vi) E₅ E_(d) 1478 E_(1b)E₂E_(iii)E₄ AlkLE_(v)E_(vi) E₅ E_(d) 1479 E_(1a)E₂E₃E_(iii)E₄ AlkLE_(v)E_(vi) E₅ E_(d) 1480 E_(1b)E₂E₃E_(iii)E₄ AlkLE_(v)E_(vi) E₅ E_(d) 1481 E_(1a)E₂E_(iv) AlkLE_(v)E_(vi) E₅ E_(d) 1482 E_(1b)E₂E_(iv) AlkLE_(v)E_(vi) E₅ E_(d) 1483 E_(1a)E₂E₃E_(iv) AlkLE_(v)E_(vi) E₅ E_(d) 1484 E_(1b)E₂E₃E_(iv) AlkLE_(v)E_(vi) E₅ E_(d) 1485 E_(1a)E₂E_(iv)E₄ AlkLE_(v)E_(vi) E₅ E_(d) 1486 E_(1b)E₂E_(iv)E₄ AlkLE_(v)E_(vi) E₅ E_(d) 1487 E_(1a)E₂E₃E_(iv)E₄ AlkLE_(v)E_(vi) E₅ E_(d) 1488 E_(1b)E₂E₃E_(iv)E₄ AlkLE_(v)E_(vi) E₅ E_(d) 1489 E_(1a)E₂ AlkLE_(v)E_(vi) E₄*E₅ E_(d) 1490 E_(1b)E₂ AlkLE_(v)E_(vi) E₄*E₅ E_(d) 1491 E_(1a)E₂E₃ AlkLE_(v)E_(vi) E₄*E₅ E_(d) 1492 E_(1b)E₂E₃ AlkLE_(v)E_(vi) E₄*E₅ E_(d) 1493 E_(1a)E₂E_(i) AlkLE_(v)E_(vi) E₄*E₅ E_(d) 1494 E_(1b)E₂E_(i) AlkLE_(v)E_(vi) E₄*E₅ E_(d) 1495 E_(1a)E₂E_(ii) AlkLE_(v)E_(vi) E₄*E₅ E_(d) 1496 E_(1b)E₂E_(ii) AlkLE_(v)E_(vi) E₄*E₅ E_(d) 1497 E_(1a)E₂E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄*E₅ E_(d) 1498 E_(1b)E₂E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄*E₅ E_(d) 1499 E_(1a)E₂E₃E_(i) AlkLE_(v)E_(vi) E₄*E₅ E_(d) 1500 E_(1b)E₂E₃E_(i) AlkLE_(v)E_(vi) E₄*E₅ E_(d) 1501 E_(1a)E₂E₃E_(ii) AlkLE_(v)E_(vi) E₄*E₅ E_(d) 1502 E_(1b)E₂E₃E_(ii) AlkLE_(v)E_(vi) E₄*E₅ E_(d) 1503 E_(1a)E₂E₃E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄*E₅ E_(d) 1504 E_(1b)E₂E₃E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄*E₅ E_(d) 1505 E_(1a)E₂E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(d) 1506 E_(1b)E₂E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(d) 1507 E_(1a)E₂E₃E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(d) 1508 E_(1b)E₂E₃E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(d) 1509 E_(1a)E₂E_(i)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(d) 1510 E_(1b)E₂E_(i)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(d) 1511 E_(1a)E₂E_(ii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(d) 1512 E_(1b)E₂E_(ii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(d) 1513 E_(1a)E₂E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(d) 1514 E_(1b)E₂E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(d) 1515 E_(1a)E₂E₃E_(i)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(d) 1516 E_(1b)E₂E₃E_(i)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(d) 1517 E_(1a)E₂E₃E_(ii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(d) 1518 E_(1b)E₂E₃E_(ii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(d) 1519 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(d) 1520 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(d) 1521 E_(1a)E₂E_(iii) AlkLE_(v)E_(vi) E₄*E₅ E_(d) 1522 E_(1b)E₂E_(iii) AlkLE_(v)E_(vi) E₄*E₅ E_(d) 1523 E_(1a)E₂E₃E_(iii) AlkLE_(v)E_(vi) E₄*E₅ E_(d) 1524 E_(1b)E₂E₃E_(iii) AlkLE_(v)E_(vi) E₄*E₅ E_(d) 1525 E_(1a)E₂E_(iii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(d) 1526 E_(1b)E₂E_(iii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(d) 1527 E_(1a)E₂E₃E_(iii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(d) 1528 E_(1b)E₂E₃E_(iii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(d) 1529 E_(1a)E₂E_(iv) AlkLE_(v)E_(vi) E₄*E₅ E_(d) 1530 E_(1b)E₂E_(iv) AlkLE_(v)E_(vi) E₄*E₅ E_(d) 1531 E_(1a)E₂E₃E_(iv) AlkLE_(v)E_(vi) E₄*E₅ E_(d) 1532 E_(1b)E₂E₃E_(iv) AlkLE_(v)E_(vi) E₄*E₅ E_(d) 1533 E_(1a)E₂E_(iv)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(d) 1534 E_(1b)E₂E_(iv)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(d) 1535 E_(1a)E₂E₃E_(iv)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(d) 1536 E_(1b)E₂E₃E_(iv)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(d) 1537 E_(1a)E₂ E_(v)E_(vi) E_(e) 1538 E_(1b)E₂ E_(v)E_(vi) E_(e) 1539 E_(1a)E₂E₃ E_(v)E_(vi) E_(e) 1540 E_(1b)E₂E₃ E_(v)E_(vi) E_(e) 1541 E_(1a)E₂E_(i) E_(v)E_(vi) E_(e) 1542 E_(1b)E₂E_(i) E_(v)E_(vi) E_(e) 1543 E_(1a)E₂E_(ii) E_(v)E_(vi) E_(e) 1544 E_(1b)E₂E_(ii) E_(v)E_(vi) E_(e) 1545 E_(1a)E₂E_(ii)E_(iib) E_(v)E_(vi) E_(e) 1546 E_(1b)E₂E_(ii)E_(iib) E_(v)E_(vi) E_(e) 1547 E_(1a)E₂E₃E_(i) E_(v)E_(vi) E_(e) 1548 E_(1b)E₂E₃E_(i) E_(v)E_(vi) E_(e) 1549 E_(1a)E₂E₃E_(ii) E_(v)E_(vi) E_(e) 1550 E_(1b)E₂E₃E_(ii) E_(v)E_(vi) E_(e) 1551 E_(1a)E₂E₃E_(ii)E_(iib) E_(v)E_(vi) E_(e) 1552 E_(1b)E₂E₃E_(ii)E_(iib) E_(v)E_(vi) E_(e) 1553 E_(1a)E₂E₄ E_(v)E_(vi) E_(e) 1554 E_(1b)E₂E₄ E_(v)E_(vi) E_(e) 1555 E_(1a)E₂E₃E₄ E_(v)E_(vi) E_(e) 1556 E_(1b)E₂E₃E₄ E_(v)E_(vi) E_(e) 1557 E_(1a)E₂E_(i)E₄ E_(v)E_(vi) E_(e) 1558 E_(1b)E₂E_(i)E₄ E_(v)E_(vi) E_(e) 1559 E_(1a)E₂E_(ii)E₄ E_(v)E_(vi) E_(e) 1560 E_(1b)E₂E_(ii)E₄ E_(v)E_(vi) E_(e) 1561 E_(1a)E₂E_(ii)E_(iib)E₄ E_(v)E_(vi) E_(e) 1562 E_(1b)E₂E_(ii)E_(iib)E₄ E_(v)E_(vi) E_(e) 1563 E_(1a)E₂E₃E_(i)E₄ E_(v)E_(vi) E_(e) 1564 E_(1b)E₂E₃E_(i)E₄ E_(v)E_(vi) E_(e) 1565 E_(1a)E₂E₃E_(ii)E₄ E_(v)E_(vi) E_(e) 1566 E_(1b)E₂E₃E_(ii)E₄ E_(v)E_(vi) E_(e) 1567 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E_(v)E_(vi) E_(e) 1568 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E_(v)E_(vi) E_(e) 1569 E_(1a)E₂E_(iii) E_(v)E_(vi) E_(e) 1570 E_(1b)E₂E_(iii) E_(v)E_(vi) E_(e) 1571 E_(1a)E₂E₃E_(iii) E_(v)E_(vi) E_(e) 1572 E_(1b)E₂E₃E_(iii) E_(v)E_(vi) E_(e) 1573 E_(1a)E₂E_(iii)E₄ E_(v)E_(vi) E_(e) 1574 E_(1b)E₂E_(iii)E₄ E_(v)E_(vi) E_(e) 1575 E_(1a)E₂E₃E_(iii)E₄ E_(v)E_(vi) E_(e) 1576 E_(1b)E₂E₃E_(iii)E₄ E_(v)E_(vi) E_(e) 1577 E_(1a)E₂E_(iv) E_(v)E_(vi) E_(e) 1578 E_(1b)E₂E_(iv) E_(v)E_(vi) E_(e) 1579 E_(1a)E₂E₃E_(iv) E_(v)E_(vi) E_(e) 1580 E_(1b)E₂E₃E_(iv) E_(v)E_(vi) E_(e) 1581 E_(1a)E₂E_(iv)E₄ E_(v)E_(vi) E_(e) 1582 E_(1b)E₂E_(iv)E₄ E_(v)E_(vi) E_(e) 1583 E_(1a)E₂E₃E_(iv)E₄ E_(v)E_(vi) E_(e) 1584 E_(1b)E₂E₃E_(iv)E₄ E_(v)E_(vi) E_(e) 1585 E_(1a)E₂ E_(v)E_(vi) E₄* E_(e) 1586 E_(1b)E₂ E_(v)E_(vi) E₄* E_(e) 1587 E_(1a)E₂E₃ E_(v)E_(vi) E₄* E_(e) 1588 E_(1b)E₂E₃ E_(v)E_(vi) E₄* E_(e) 1589 E_(1a)E₂E_(i) E_(v)E_(vi) E₄* E_(e) 1590 E_(1b)E₂E_(i) E_(v)E_(vi) E₄* E_(e) 1591 E_(1a)E₂E_(ii) E_(v)E_(vi) E₄* E_(e) 1592 E_(1b)E₂E_(ii) E_(v)E_(vi) E₄* E_(e) 1593 E_(1a)E₂E_(ii)E_(iib) E_(v)E_(vi) E₄* E_(e) 1594 E_(1b)E₂E_(ii)E_(iib) E_(v)E_(vi) E₄* E_(e) 1595 E_(1a)E₂E₃E_(i) E_(v)E_(vi) E₄* E_(e) 1596 E_(1b)E₂E₃E_(i) E_(v)E_(vi) E₄* E_(e) 1597 E_(1a)E₂E₃E_(ii) E_(v)E_(vi) E₄* E_(e) 1598 E_(1b)E₂E₃E_(ii) E_(v)E_(vi) E₄* E_(e) 1599 E_(1a)E₂E₃E_(ii)E_(iib) E_(v)E_(vi) E₄* E_(e) 1600 E_(1b)E₂E₃E_(ii)E_(iib) E_(v)E_(vi) E₄* E_(e) 1601 E_(1a)E₂E₄ E_(v)E_(vi) E₄* E_(e) 1602 E_(1b)E₂E₄ E_(v)E_(vi) E₄* E_(e) 1603 E_(1a)E₂E₃E₄ E_(v)E_(vi) E₄* E_(e) 1604 E_(1b)E₂E₃E₄ E_(v)E_(vi) E₄* E_(e) 1605 E_(1a)E₂E_(i)E₄ E_(v)E_(vi) E₄* E_(e) 1606 E_(1b)E₂E_(i)E₄ E_(v)E_(vi) E₄* E_(e) 1607 E_(1a)E₂E_(ii)E₄ E_(v)E_(vi) E₄* E_(e) 1608 E_(1b)E₂E_(ii)E₄ E_(v)E_(vi) E₄* E_(e) 1609 E_(1a)E₂E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* E_(e) 1610 E_(1b)E₂E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* E_(e) 1611 E_(1a)E₂E₃E_(i)E₄ E_(v)E_(vi) E₄* E_(e) 1612 E_(1b)E₂E₃E_(i)E₄ E_(v)E_(vi) E₄* E_(e) 1613 E_(1a)E₂E₃E_(ii)E₄ E_(v)E_(vi) E₄* E_(e) 1614 E_(1b)E₂E₃E_(ii)E₄ E_(v)E_(vi) E₄* E_(e) 1615 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* E_(e) 1616 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* E_(e) 1617 E_(1a)E₂E_(iii) E_(v)E_(vi) E₄* E_(e) 1618 E_(1b)E₂E_(iii) E_(v)E_(vi) E₄* E_(e) 1619 E_(1a)E₂E₃E_(iii) E_(v)E_(vi) E₄* E_(e) 1620 E_(1b)E₂E₃E_(iii) E_(v)E_(vi) E₄* E_(e) 1621 E_(1a)E₂E_(iii)E₄ E_(v)E_(vi) E₄* E_(e) 1622 E_(1b)E₂E_(iii)E₄ E_(v)E_(vi) E₄* E_(e) 1623 E_(1a)E₂E₃E_(iii)E₄ E_(v)E_(vi) E₄* E_(e) 1624 E_(1b)E₂E₃E_(iii)E₄ E_(v)E_(vi) E₄* E_(e) 1625 E_(1a)E₂E_(iv) E_(v)E_(vi) E₄* E_(e) 1626 E_(1b)E₂E_(iv) E_(v)E_(vi) E₄* E_(e) 1627 E_(1a)E₂E₃E_(iv) E_(v)E_(vi) E₄* E_(e) 1628 E_(1b)E₂E₃E_(iv) E_(v)E_(vi) E₄* E_(e) 1629 E_(1a)E₂E_(iv)E₄ E_(v)E_(vi) E₄* E_(e) 1630 E_(1b)E₂E_(iv)E₄ E_(v)E_(vi) E₄* E_(e) 1631 E_(1a)E₂E₃E_(iv)E₄ E_(v)E_(vi) E₄* E_(e) 1632 E_(1b)E₂E₃E_(iv)E₄ E_(v)E_(vi) E₄* E_(e) 1633 E_(1a)E₂ E_(v)E_(vi) E₅ E_(e) 1634 E_(1b)E₂ E_(v)E_(vi) E₅ E_(e) 1635 E_(1a)E₂E₃ E_(v)E_(vi) E₅ E_(e) 1636 E_(1b)E₂E₃ E_(v)E_(vi) E₅ E_(e) 1637 E_(1a)E₂E_(i) E_(v)E_(vi) E₅ E_(e) 1638 E_(1b)E₂E_(i) E_(v)E_(vi) E₅ E_(e) 1639 E_(1a)E₂E_(ii) E_(v)E_(vi) E₅ E_(e) 1640 E_(1b)E₂E_(ii) E_(v)E_(vi) E₅ E_(e) 1641 E_(1a)E₂E_(ii)E_(iib) E_(v)E_(vi) E₅ E_(e) 1642 E_(1b)E₂E_(ii)E_(iib) E_(v)E_(vi) E₅ E_(e) 1643 E_(1a)E₂E₃E_(i) E_(v)E_(vi) E₅ E_(e) 1644 E_(1b)E₂E₃E_(i) E_(v)E_(vi) E₅ E_(e) 1645 E_(1a)E₂E₃E_(ii) E_(v)E_(vi) E₅ E_(e) 1646 E_(1b)E₂E₃E_(ii) E_(v)E_(vi) E₅ E_(e) 1647 E_(1a)E₂E₃E_(ii)E_(iib) E_(v)E_(vi) E₅ E_(e) 1648 E_(1b)E₂E₃E_(ii)E_(iib) E_(v)E_(vi) E₅ E_(e) 1649 E_(1a)E₂E₄ E_(v)E_(vi) E₅ E_(e) 1650 E_(1b)E₂E₄ E_(v)E_(vi) E₅ E_(e) 1651 E_(1a)E₂E₃E₄ E_(v)E_(vi) E₅ E_(e) 1652 E_(1b)E₂E₃E₄ E_(v)E_(vi) E₅ E_(e) 1653 E_(1a)E₂E_(i)E₄ E_(v)E_(vi) E₅ E_(e) 1654 E_(1b)E₂E_(i)E₄ E_(v)E_(vi) E₅ E_(e) 1655 E_(1a)E₂E_(ii)E₄ E_(v)E_(vi) E₅ E_(e) 1656 E_(1b)E₂E_(ii)E₄ E_(v)E_(vi) E₅ E_(e) 1657 E_(1a)E₂E_(ii)E_(iib)E₄ E_(v)E_(vi) E₅ E_(e) 1658 E_(1b)E₂E_(ii)E_(iib)E₄ E_(v)E_(vi) E₅ E_(e) 1659 E_(1a)E₂E₃E_(i)E₄ E_(v)E_(vi) E₅ E_(e) 1660 E_(1b)E₂E₃E_(i)E₄ E_(v)E_(vi) E₅ E_(e) 1661 E_(1a)E₂E₃E_(ii)E₄ E_(v)E_(vi) E₅ E_(e) 1662 E_(1b)E₂E₃E_(ii)E₄ E_(v)E_(vi) E₅ E_(e) 1663 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E_(v)E_(vi) E₅ E_(e) 1664 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E_(v)E_(vi) E₅ E_(e) 1665 E_(1a)E₂E_(iii) E_(v)E_(vi) E₅ E_(e) 1666 E_(1b)E₂E_(iii) E_(v)E_(vi) E₅ E_(e) 1667 E_(1a)E₂E₃E_(iii) E_(v)E_(vi) E₅ E_(e) 1668 E_(1b)E₂E₃E_(iii) E_(v)E_(vi) E₅ E_(e) 1669 E_(1a)E₂E_(iii)E₄ E_(v)E_(vi) E₅ E_(e) 1670 E_(1b)E₂E_(iii)E₄ E_(v)E_(vi) E₅ E_(e) 1671 E_(1a)E₂E₃E_(iii)E₄ E_(v)E_(vi) E₅ E_(e) 1672 E_(1b)E₂E₃E_(iii)E₄ E_(v)E_(vi) E₅ E_(e) 1673 E_(1a)E₂E_(iv) E_(v)E_(vi) E₅ E_(e) 1674 E_(1b)E₂E_(iv) E_(v)E_(vi) E₅ E_(e) 1675 E_(1a)E₂E₃E_(iv) E_(v)E_(vi) E₅ E_(e) 1676 E_(1b)E₂E₃E_(iv) E_(v)E_(vi) E₅ E_(e) 1677 E_(1a)E₂E_(iv)E₄ E_(v)E_(vi) E₅ E_(e) 1678 E_(1b)E₂E_(iv)E₄ E_(v)E_(vi) E₅ E_(e) 1679 E_(1a)E₂E₃E_(iv)E₄ E_(v)E_(vi) E₅ E_(e) 1680 E_(1b)E₂E₃E_(iv)E₄ E_(v)E_(vi) E₅ E_(e) 1681 E_(1a)E₂ E_(v)E_(vi) E₄*E₅ E_(e) 1682 E_(1b)E₂ E_(v)E_(vi) E₄*E₅ E_(e) 1683 E_(1a)E₂E₃ E_(v)E_(vi) E₄*E₅ E_(e) 1684 E_(1b)E₂E₃ E_(v)E_(vi) E₄*E₅ E_(e) 1685 E_(1a)E₂E_(i) E_(v)E_(vi) E₄*E₅ E_(e) 1686 E_(1b)E₂E_(i) E_(v)E_(vi) E₄*E₅ E_(e) 1687 E_(1a)E₂E_(ii) E_(v)E_(vi) E₄*E₅ E_(e) 1688 E_(1b)E₂E_(ii) E_(v)E_(vi) E₄*E₅ E_(e) 1689 E_(1a)E₂E_(ii)E_(iib) E_(v)E_(vi) E₄*E₅ E_(e) 1690 E_(1b)E₂E_(ii)E_(iib) E_(v)E_(vi) E₄*E₅ E_(e) 1691 E_(1a)E₂E₃E_(i) E_(v)E_(vi) E₄*E₅ E_(e) 1692 E_(1b)E₂E₃E_(i) E_(v)E_(vi) E₄*E₅ E_(e) 1693 E_(1a)E₂E₃E_(ii) E_(v)E_(vi) E₄*E₅ E_(e) 1694 E_(1b)E₂E₃E_(ii) E_(v)E_(vi) E₄*E₅ E_(e) 1695 E_(1a)E₂E₃E_(ii)E_(iib) E_(v)E_(vi) E₄*E₅ E_(e) 1696 E_(1b)E₂E₃E_(ii)E_(iib) E_(v)E_(vi) E₄*E₅ E_(e) 1697 E_(1a)E₂E₄ E_(v)E_(vi) E₄*E₅ E_(e) 1698 E_(1b)E₂E₄ E_(v)E_(vi) E₄*E₅ E_(e) 1699 E_(1a)E₂E₃E₄ E_(v)E_(vi) E₄*E₅ E_(e) 1700 E_(1b)E₂E₃E₄ E_(v)E_(vi) E₄*E₅ E_(e) 1701 E_(1a)E₂E_(i)E₄ E_(v)E_(vi) E₄*E₅ E_(e) 1702 E_(1b)E₂E_(i)E₄ E_(v)E_(vi) E₄*E₅ E_(e) 1703 E_(1a)E₂E_(ii)E₄ E_(v)E_(vi) E₄*E₅ E_(e) 1704 E_(1b)E₂E_(ii)E₄ E_(v)E_(vi) E₄*E₅ E_(e) 1705 E_(1a)E₂E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄*E₅ E_(e) 1706 E_(1b)E₂E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄*E₅ E_(e) 1707 E_(1a)E₂E₃E_(i)E₄ E_(v)E_(vi) E₄*E₅ E_(e) 1708 E_(1b)E₂E₃E_(i)E₄ E_(v)E_(vi) E₄*E₅ E_(e) 1709 E_(1a)E₂E₃E_(ii)E₄ E_(v)E_(vi) E₄*E₅ E_(e) 1710 E_(1b)E₂E₃E_(ii)E₄ E_(v)E_(vi) E₄*E₅ E_(e) 1711 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄*E₅ E_(e) 1712 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄*E₅ E_(e) 1713 E_(1a)E₂E_(iii) E_(v)E_(vi) E₄*E₅ E_(e) 1714 E_(1b)E₂E_(iii) E_(v)E_(vi) E₄*E₅ E_(e) 1715 E_(1a)E₂E₃E_(iii) E_(v)E_(vi) E₄*E₅ E_(e) 1716 E_(1b)E₂E₃E_(iii) E_(v)E_(vi) E₄*E₅ E_(e) 1717 E_(1a)E₂E_(iii)E₄ E_(v)E_(vi) E₄*E₅ E_(e) 1718 E_(1b)E₂E_(iii)E₄ E_(v)E_(vi) E₄*E₅ E_(e) 1719 E_(1a)E₂E₃E_(iii)E₄ E_(v)E_(vi) E₄*E₅ E_(e) 1720 E_(1b)E₂E₃E_(iii)E₄ E_(v)E_(vi) E₄*E₅ E_(e) 1721 E_(1a)E₂E_(iv) E_(v)E_(vi) E₄*E₅ E_(e) 1722 E_(1b)E₂E_(iv) E_(v)E_(vi) E₄*E₅ E_(e) 1723 E_(1a)E₂E₃E_(iv) E_(v)E_(vi) E₄*E₅ E_(e) 1724 E_(1b)E₂E₃E_(iv) E_(v)E_(vi) E₄*E₅ E_(e) 1725 E_(1a)E₂E_(iv)E₄ E_(v)E_(vi) E₄*E₅ E_(e) 1726 E_(1b)E₂E_(iv)E₄ E_(v)E_(vi) E₄*E₅ E_(e) 1727 E_(1a)E₂E₃E_(iv)E₄ E_(v)E_(vi) E₄*E₅ E_(e) 1728 E_(1b)E₂E₃E_(iv)E₄ E_(v)E_(vi) E₄*E₅ E_(e) 1729 E_(1a)E₂ AlkLE_(v)E_(vi) E_(e) 1730 E_(1b)E₂ AlkLE_(v)E_(vi) E_(e) 1731 E_(1a)E₂E₃ AlkLE_(v)E_(vi) E_(e) 1732 E_(1b)E₂E₃ AlkLE_(v)E_(vi) E_(e) 1733 E_(1a)E₂E_(i) AlkLE_(v)E_(vi) E_(e) 1734 E_(1b)E₂E_(i) AlkLE_(v)E_(vi) E_(e) 1735 E_(1a)E₂E_(ii) AlkLE_(v)E_(vi) E_(e) 1736 E_(1b)E₂E_(ii) AlkLE_(v)E_(vi) E_(e) 1737 E_(1a)E₂E_(ii)E_(iib) AlkLE_(v)E_(vi) E_(e) 1738 E_(1b)E₂E_(ii)E_(iib) AlkLE_(v)E_(vi) E_(e) 1739 E_(1a)E₂E₃E_(i) AlkLE_(v)E_(vi) E_(e) 1740 E_(1b)E₂E₃E_(i) AlkLE_(v)E_(vi) E_(e) 1741 E_(1a)E₂E₃E_(ii) AlkLE_(v)E_(vi) E_(e) 1742 E_(1b)E₂E₃E_(ii) AlkLE_(v)E_(vi) E_(e) 1743 E_(1a)E₂E₃E_(ii)E_(iib) AlkLE_(v)E_(vi) E_(e) 1744 E_(1b)E₂E₃E_(ii)E_(iib) AlkLE_(v)E_(vi) E_(e) 1745 E_(1a)E₂E₄ AlkLE_(v)E_(vi) E_(e) 1746 E_(1b)E₂E₄ AlkLE_(v)E_(vi) E_(e) 1747 E_(1a)E₂E₃E₄ AlkLE_(v)E_(vi) E_(e) 1748 E_(1b)E₂E₃E₄ AlkLE_(v)E_(vi) E_(e) 1749 E_(1a)E₂E_(i)E₄ AlkLE_(v)E_(vi) E_(e) 1750 E_(1b)E₂E_(i)E₄ AlkLE_(v)E_(vi) E_(e) 1751 E_(1a)E₂E_(ii)E₄ AlkLE_(v)E_(vi) E_(e) 1752 E_(1b)E₂E_(ii)E₄ AlkLE_(v)E_(vi) E_(e) 1753 E_(1a)E₂E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E_(e) 1754 E_(1b)E₂E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E_(e) 1755 E_(1a)E₂E₃E_(i)E₄ AlkLE_(v)E_(vi) E_(e) 1756 E_(1b)E₂E₃E_(i)E₄ AlkLE_(v)E_(vi) E_(e) 1757 E_(1a)E₂E₃E_(ii)E₄ AlkLE_(v)E_(vi) E_(e) 1758 E_(1b)E₂E₃E_(ii)E₄ AlkLE_(v)E_(vi) E_(e) 1759 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E_(e) 1760 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E_(e) 1761 E_(1a)E₂E_(iii) AlkLE_(v)E_(vi) E_(e) 1762 E_(1b)E₂E_(iii) AlkLE_(v)E_(vi) E_(e) 1763 E_(1a)E₂E₃E_(iii) AlkLE_(v)E_(vi) E_(e) 1764 E_(1b)E₂E₃E_(iii) AlkLE_(v)E_(vi) E_(e) 1765 E_(1a)E₂E_(iii)E₄ AlkLE_(v)E_(vi) E_(e) 1766 E_(1b)E₂E_(iii)E₄ AlkLE_(v)E_(vi) E_(e) 1767 E_(1a)E₂E₃E_(iii)E₄ AlkLE_(v)E_(vi) E_(e) 1768 E_(1b)E₂E₃E_(iii)E₄ AlkLE_(v)E_(vi) E_(e) 1769 E_(1a)E₂E_(iv) AlkLE_(v)E_(vi) E_(e) 1770 E_(1b)E₂E_(iv) AlkLE_(v)E_(vi) E_(e) 1771 E_(1a)E₂E₃E_(iv) AlkLE_(v)E_(vi) E_(e) 1772 E_(1b)E₂E₃E_(iv) AlkLE_(v)E_(vi) E_(e) 1773 E_(1a)E₂E_(iv)E₄ AlkLE_(v)E_(vi) E_(e) 1774 E_(1b)E₂E_(iv)E₄ AlkLE_(v)E_(vi) E_(e) 1775 E_(1a)E₂E₃E_(iv)E₄ AlkLE_(v)E_(vi) E_(e) 1776 E_(1b)E₂E₃E_(iv)E₄ AlkLE_(v)E_(vi) E_(e) 1777 E_(1a)E₂ AlkLE_(v)E_(vi) E₄* E_(e) 1778 E_(1b)E₂ AlkLE_(v)E_(vi) E₄* E_(e) 1779 E_(1a)E₂E₃ AlkLE_(v)E_(vi) E₄* E_(e) 1780 E_(1b)E₂E₃ AlkLE_(v)E_(vi) E₄* E_(e) 1781 E_(1a)E₂E_(i) AlkLE_(v)E_(vi) E₄* E_(e) 1782 E_(1b)E₂E_(i) AlkLE_(v)E_(vi) E₄* E_(e) 1783 E_(1a)E₂E_(ii) AlkLE_(v)E_(vi) E₄* E_(e) 1784 E_(1b)E₂E_(ii) AlkLE_(v)E_(vi) E₄* E_(e) 1785 E_(1a)E₂E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* E_(e) 1786 E_(1b)E₂E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* E_(e) 1787 E_(1a)E₂E₃E_(i) AlkLE_(v)E_(vi) E₄* E_(e) 1788 E_(1b)E₂E₃E_(i) AlkLE_(v)E_(vi) E₄* E_(e) 1789 E_(1a)E₂E₃E_(ii) AlkLE_(v)E_(vi) E₄* E_(e) 1790 E_(1b)E₂E₃E_(ii) AlkLE_(v)E_(vi) E₄* E_(e) 1791 E_(1a)E₂E₃E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* E_(e) 1792 E_(1b)E₂E₃E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* E_(e) 1793 E_(1a)E₂E₄ AlkLE_(v)E_(vi) E₄* E_(e) 1794 E_(1b)E₂E₄ AlkLE_(v)E_(vi) E₄* E_(e) 1795 E_(1a)E₂E₃E₄ AlkLE_(v)E_(vi) E₄* E_(e) 1796 E_(1b)E₂E₃E₄ AlkLE_(v)E_(vi) E₄* E_(e) 1797 E_(1a)E₂E_(i)E₄ AlkLE_(v)E_(vi) E₄* E_(e) 1798 E_(1b)E₂E_(i)E₄ AlkLE_(v)E_(vi) E₄* E_(e) 1799 E_(1a)E₂E_(ii)E₄ AlkLE_(v)E_(vi) E₄* E_(e) 1800 E_(1b)E₂E_(ii)E₄ AlkLE_(v)E_(vi) E₄* E_(e) 1801 E_(1a)E₂E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* E_(e) 1802 E_(1b)E₂E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* E_(e) 1803 E_(1a)E₂E₃E_(i)E₄ AlkLE_(v)E_(vi) E₄* E_(e) 1804 E_(1b)E₂E₃E_(i)E₄ AlkLE_(v)E_(vi) E₄* E_(e) 1805 E_(1a)E₂E₃E_(ii)E₄ AlkLE_(v)E_(vi) E₄* E_(e) 1806 E_(1b)E₂E₃E_(ii)E₄ AlkLE_(v)E_(vi) E₄* E_(e) 1807 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* E_(e) 1808 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* E_(e) 1809 E_(1a)E₂E_(iii) AlkLE_(v)E_(vi) E₄* E_(e) 1810 E_(1b)E₂E_(iii) AlkLE_(v)E_(vi) E₄* E_(e) 1811 E_(1a)E₂E₃E_(iii) AlkLE_(v)E_(vi) E₄* E_(e) 1812 E_(1b)E₂E₃E_(iii) AlkLE_(v)E_(vi) E₄* E_(e) 1813 E_(1a)E₂E_(iii)E₄ AlkLE_(v)E_(vi) E₄* E_(e) 1814 E_(1b)E₂E_(iii)E₄ AlkLE_(v)E_(vi) E₄* E_(e) 1815 E_(1a)E₂E₃E_(iii)E₄ AlkLE_(v)E_(vi) E₄* E_(e) 1816 E_(1b)E₂E₃E_(iii)E₄ AlkLE_(v)E_(vi) E₄* E_(e) 1817 E_(1a)E₂E_(iv) AlkLE_(v)E_(vi) E₄* E_(e) 1818 E_(1b)E₂E_(iv) AlkLE_(v)E_(vi) E₄* E_(e) 1819 E_(1a)E₂E₃E_(iv) AlkLE_(v)E_(vi) E₄* E_(e) 1820 E_(1b)E₂E₃E_(iv) AlkLE_(v)E_(vi) E₄* E_(e) 1821 E_(1a)E₂E_(iv)E₄ AlkLE_(v)E_(vi) E₄* E_(e) 1822 E_(1b)E₂E_(iv)E₄ AlkLE_(v)E_(vi) E₄* E_(e) 1823 E_(1a)E₂E₃E_(iv)E₄ AlkLE_(v)E_(vi) E₄* E_(e) 1824 E_(1b)E₂E₃E_(iv)E₄ AlkLE_(v)E_(vi) E₄* E_(e) 1825 E_(1a)E₂ AlkLE_(v)E_(vi) E₅ E_(e) 1826 E_(1b)E₂ AlkLE_(v)E_(vi) E₅ E_(e) 1827 E_(1a)E₂E₃ AlkLE_(v)E_(vi) E₅ E_(e) 1828 E_(1b)E₂E₃ AlkLE_(v)E_(vi) E₅ E_(e) 1829 E_(1a)E₂E_(i) AlkLE_(v)E_(vi) E₅ E_(e) 1830 E_(1b)E₂E_(i) AlkLE_(v)E_(vi) E₅ E_(e) 1831 E_(1a)E₂E_(ii) AlkLE_(v)E_(vi) E₅ E_(e) 1832 E_(1b)E₂E_(ii) AlkLE_(v)E_(vi) E₅ E_(e) 1833 E_(1a)E₂E_(ii)E_(iib) AlkLE_(v)E_(vi) E₅ E_(e) 1834 E_(1b)E₂E_(ii)E_(iib) AlkLE_(v)E_(vi) E₅ E_(e) 1835 E_(1a)E₂E₃E_(i) AlkLE_(v)E_(vi) E₅ E_(e) 1836 E_(1b)E₂E₃E_(i) AlkLE_(v)E_(vi) E₅ E_(e) 1837 E_(1a)E₂E₃E_(ii) AlkLE_(v)E_(vi) E₅ E_(e) 1838 E_(1b)E₂E₃E_(ii) AlkLE_(v)E_(vi) E₅ E_(e) 1839 E_(1a)E₂E₃E_(ii)E_(iib) AlkLE_(v)E_(vi) E₅ E_(e) 1840 E_(1b)E₂E₃E_(ii)E_(iib) AlkLE_(v)E_(vi) E₅ E_(e) 1841 E_(1a)E₂E₄ AlkLE_(v)E_(vi) E₅ E_(e) 1842 E_(1b)E₂E₄ AlkLE_(v)E_(vi) E₅ E_(e) 1843 E_(1a)E₂E₃E₄ AlkLE_(v)E_(vi) E₅ E_(e) 1844 E_(1b)E₂E₃E₄ AlkLE_(v)E_(vi) E₅ E_(e) 1845 E_(1a)E₂E_(i)E₄ AlkLE_(v)E_(vi) E₅ E_(e) 1846 E_(1b)E₂E_(i)E₄ AlkLE_(v)E_(vi) E₅ E_(e) 1847 E_(1a)E₂E_(ii)E₄ AlkLE_(v)E_(vi) E₅ E_(e) 1848 E_(1b)E₂E_(ii)E₄ AlkLE_(v)E_(vi) E₅ E_(e) 1849 E_(1a)E₂E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₅ E_(e) 1850 E_(1b)E₂E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₅ E_(e) 1851 E_(1a)E₂E₃E_(i)E₄ AlkLE_(v)E_(vi) E₅ E_(e) 1852 E_(1b)E₂E₃E_(i)E₄ AlkLE_(v)E_(vi) E₅ E_(e) 1853 E_(1a)E₂E₃E_(ii)E₄ AlkLE_(v)E_(vi) E₅ E_(e) 1854 E_(1b)E₂E₃E_(ii)E₄ AlkLE_(v)E_(vi) E₅ E_(e) 1855 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₅ E_(e) 1856 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₅ E_(e) 1857 E_(1a)E₂E_(iii) AlkLE_(v)E_(vi) E₅ E_(e) 1858 E_(1b)E₂E_(iii) AlkLE_(v)E_(vi) E₅ E_(e) 1859 E_(1a)E₂E₃E_(iii) AlkLE_(v)E_(vi) E₅ E_(e) 1860 E_(1b)E₂E₃E_(iii) AlkLE_(v)E_(vi) E₅ E_(e) 1861 E_(1a)E₂E_(iii)E₄ AlkLE_(v)E_(vi) E₅ E_(e) 1862 E_(1b)E₂E_(iii)E₄ AlkLE_(v)E_(vi) E₅ E_(e) 1863 E_(1a)E₂E₃E_(iii)E₄ AlkLE_(v)E_(vi) E₅ E_(e) 1864 E_(1b)E₂E₃E_(iii)E₄ AlkLE_(v)E_(vi) E₅ E_(e) 1865 E_(1a)E₂E_(iv) AlkLE_(v)E_(vi) E₅ E_(e) 1866 E_(1b)E₂E_(iv) AlkLE_(v)E_(vi) E₅ E_(e) 1867 E_(1a)E₂E₃E_(iv) AlkLE_(v)E_(vi) E₅ E_(e) 1868 E_(1b)E₂E₃E_(iv) AlkLE_(v)E_(vi) E₅ E_(e) 1869 E_(1a)E₂E_(iv)E₄ AlkLE_(v)E_(vi) E₅ E_(e) 1870 E_(1b)E₂E_(iv)E₄ AlkLE_(v)E_(vi) E₅ E_(e) 1871 E_(1a)E₂E₃E_(iv)E₄ AlkLE_(v)E_(vi) E₅ E_(e) 1872 E_(1b)E₂E₃E_(iv)E₄ AlkLE_(v)E_(vi) E₅ E_(e) 1873 E_(1a)E₂ AlkLE_(v)E_(vi) E₄*E₅ E_(e) 1874 E_(1b)E₂ AlkLE_(v)E_(vi) E₄*E₅ E_(e) 1875 E_(1a)E₂E₃ AlkLE_(v)E_(vi) E₄*E₅ E_(e) 1876 E_(1b)E₂E₃ AlkLE_(v)E_(vi) E₄*E₅ E_(e) 1877 E_(1a)E₂E_(i) AlkLE_(v)E_(vi) E₄*E₅ E_(e) 1878 E_(1b)E₂E_(i) AlkLE_(v)E_(vi) E₄*E₅ E_(e) 1879 E_(1a)E₂E_(ii) AlkLE_(v)E_(vi) E₄*E₅ E_(e) 1880 E_(1b)E₂E_(ii) AlkLE_(v)E_(vi) E₄*E₅ E_(e) 1881 E_(1a)E₂E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄*E₅ E_(e) 1882 E_(1b)E₂E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄*E₅ E_(e) 1883 E_(1a)E₂E₃E_(i) AlkLE_(v)E_(vi) E₄*E₅ E_(e) 1884 E_(1b)E₂E₃E_(i) AlkLE_(v)E_(vi) E₄*E₅ E_(e) 1885 E_(1a)E₂E₃E_(ii) AlkLE_(v)E_(vi) E₄*E₅ E_(e) 1886 E_(1b)E₂E₃E_(ii) AlkLE_(v)E_(vi) E₄*E₅ E_(e) 1887 E_(1a)E₂E₃E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄*E₅ E_(e) 1888 E_(1b)E₂E₃E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄*E₅ E_(e) 1889 E_(1a)E₂E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(e) 1890 E_(1b)E₂E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(e) 1891 E_(1a)E₂E₃E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(e) 1892 E_(1b)E₂E₃E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(e) 1893 E_(1a)E₂E_(i)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(e) 1894 E_(1b)E₂E_(i)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(e) 1895 E_(1a)E₂E_(ii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(e) 1896 E_(1b)E₂E_(ii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(e) 1897 E_(1a)E₂E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(e) 1898 E_(1b)E₂E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(e) 1899 E_(1a)E₂E₃E_(i)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(e) 1900 E_(1b)E₂E₃E_(i)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(e) 1901 E_(1a)E₂E₃E_(ii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(e) 1902 E_(1b)E₂E₃E_(ii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(e) 1903 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(e) 1904 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(e) 1905 E_(1a)E₂E_(iii) AlkLE_(v)E_(vi) E₄*E₅ E_(e) 1906 E_(1b)E₂E_(iii) AlkLE_(v)E_(vi) E₄*E₅ E_(e) 1907 E_(1a)E₂E₃E_(iii) AlkLE_(v)E_(vi) E₄*E₅ E_(e) 1908 E_(1b)E₂E₃E_(iii) AlkLE_(v)E_(vi) E₄*E₅ E_(e) 1909 E_(1a)E₂E_(iii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(e) 1910 E_(1b)E₂E_(iii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(e) 1911 E_(1a)E₂E₃E_(iii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(e) 1912 E_(1b)E₂E₃E_(iii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(e) 1913 E_(1a)E₂E_(iv) AlkLE_(v)E_(vi) E₄*E₅ E_(e) 1914 E_(1b)E₂E_(iv) AlkLE_(v)E_(vi) E₄*E₅ E_(e) 1915 E_(1a)E₂E₃E_(iv) AlkLE_(v)E_(vi) E₄*E₅ E_(e) 1916 E_(1b)E₂E₃E_(iv) AlkLE_(v)E_(vi) E₄*E₅ E_(e) 1917 E_(1a)E₂E_(iv)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(e) 1918 E_(1b)E₂E_(iv)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(e) 1919 E_(1a)E₂E₃E_(iv)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(e) 1920 E_(1b)E₂E₃E_(iv)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(e) 1921 E_(1a)E₂ E_(v)E_(vi) E_(f) 1922 E_(1b)E₂ E_(v)E_(vi) E_(f) 1923 E_(1a)E₂E₃ E_(v)E_(vi) E_(f) 1924 E_(1b)E₂E₃ E_(v)E_(vi) E_(f) 1925 E_(1a)E₂E_(i) E_(v)E_(vi) E_(f) 1926 E_(1b)E₂E_(i) E_(v)E_(vi) E_(f) 1927 E_(1a)E₂E_(ii) E_(v)E_(vi) E_(f) 1928 E_(1b)E₂E_(ii) E_(v)E_(vi) E_(f) 1929 E_(1a)E₂E_(ii)E_(iib) E_(v)E_(vi) E_(f) 1930 E_(1b)E₂E_(ii)E_(iib) E_(v)E_(vi) E_(f) 1931 E_(1a)E₂E₃E_(i) E_(v)E_(vi) E_(f) 1932 E_(1b)E₂E₃E_(i) E_(v)E_(vi) E_(f) 1933 E_(1a)E₂E₃E_(ii) E_(v)E_(vi) E_(f) 1934 E_(1b)E₂E₃E_(ii) E_(v)E_(vi) E_(f) 1935 E_(1a)E₂E₃E_(ii)E_(iib) E_(v)E_(vi) E_(f) 1936 E_(1b)E₂E₃E_(ii)E_(iib) E_(v)E_(vi) E_(f) 1937 E_(1a)E₂E₄ E_(v)E_(vi) E_(f) 1938 E_(1b)E₂E₄ E_(v)E_(vi) E_(f) 1939 E_(1a)E₂E₃E₄ E_(v)E_(vi) E_(f) 1940 E_(1b)E₂E₃E₄ E_(v)E_(vi) E_(f) 1941 E_(1a)E₂E_(i)E₄ E_(v)E_(vi) E_(f) 1942 E_(1b)E₂E_(i)E₄ E_(v)E_(vi) E_(f) 1943 E_(1a)E₂E_(ii)E₄ E_(v)E_(vi) E_(f) 1944 E_(1b)E₂E_(ii)E₄ E_(v)E_(vi) E_(f) 1945 E_(1a)E₂E_(ii)E_(iib)E₄ E_(v)E_(vi) E_(f) 1946 E_(1b)E₂E_(ii)E_(iib)E₄ E_(v)E_(vi) E_(f) 1947 E_(1a)E₂E₃E_(i)E₄ E_(v)E_(vi) E_(f) 1948 E_(1b)E₂E₃E_(i)E₄ E_(v)E_(vi) E_(f) 1949 E_(1a)E₂E₃E_(ii)E₄ E_(v)E_(vi) E_(f) 1950 E_(1b)E₂E₃E_(ii)E₄ E_(v)E_(vi) E_(f) 1951 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E_(v)E_(vi) E_(f) 1952 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E_(v)E_(vi) E_(f) 1953 E_(1a)E₂E_(iii) E_(v)E_(vi) E_(f) 1954 E_(1b)E₂E_(iii) E_(v)E_(vi) E_(f) 1955 E_(1a)E₂E₃E_(iii) E_(v)E_(vi) E_(f) 1956 E_(1b)E₂E₃E_(iii) E_(v)E_(vi) E_(f) 1957 E_(1a)E₂E_(iii)E₄ E_(v)E_(vi) E_(f) 1958 E_(1b)E₂E_(iii)E₄ E_(v)E_(vi) E_(f) 1959 E_(1a)E₂E₃E_(iii)E₄ E_(v)E_(vi) E_(f) 1960 E_(1b)E₂E₃E_(iii)E₄ E_(v)E_(vi) E_(f) 1961 E_(1a)E₂E_(iv) E_(v)E_(vi) E_(f) 1962 E_(1b)E₂E_(iv) E_(v)E_(vi) E_(f) 1963 E_(1a)E₂E₃E_(iv) E_(v)E_(vi) E_(f) 1964 E_(1b)E₂E₃E_(iv) E_(v)E_(vi) E_(f) 1965 E_(1a)E₂E_(iv)E₄ E_(v)E_(vi) E_(f) 1966 E_(1b)E₂E_(iv)E₄ E_(v)E_(vi) E_(f) 1967 E_(1a)E₂E₃E_(iv)E₄ E_(v)E_(vi) E_(f) 1968 E_(1b)E₂E₃E_(iv)E₄ E_(v)E_(vi) E_(f) 1969 E_(1a)E₂ E_(v)E_(vi) E₄* E_(f) 1970 E_(1b)E₂ E_(v)E_(vi) E₄* E_(f) 1971 E_(1a)E₂E₃ E_(v)E_(vi) E₄* E_(f) 1972 E_(1b)E₂E₃ E_(v)E_(vi) E₄* E_(f) 1973 E_(1a)E₂E_(i) E_(v)E_(vi) E₄* E_(f) 1974 E_(1b)E₂E_(i) E_(v)E_(vi) E₄* E_(f) 1975 E_(1a)E₂E_(ii) E_(v)E_(vi) E₄* E_(f) 1976 E_(1b)E₂E_(ii) E_(v)E_(vi) E₄* E_(f) 1977 E_(1a)E₂E_(ii)E_(iib) E_(v)E_(vi) E₄* E_(f) 1978 E_(1b)E₂E_(ii)E_(iib) E_(v)E_(vi) E₄* E_(f) 1979 E_(1a)E₂E₃E_(i) E_(v)E_(vi) E₄* E_(f) 1980 E_(1b)E₂E₃E_(i) E_(v)E_(vi) E₄* E_(f) 1981 E_(1a)E₂E₃E_(ii) E_(v)E_(vi) E₄* E_(f) 1982 E_(1b)E₂E₃E_(ii) E_(v)E_(vi) E₄* E_(f) 1983 E_(1a)E₂E₃E_(ii)E_(iib) E_(v)E_(vi) E₄* E_(f) 1984 E_(1b)E₂E₃E_(ii)E_(iib) E_(v)E_(vi) E₄* E_(f) 1985 E_(1a)E₂E₄ E_(v)E_(vi) E₄* E_(f) 1986 E_(1b)E₂E₄ E_(v)E_(vi) E₄* E_(f) 1987 E_(1a)E₂E₃E₄ E_(v)E_(vi) E₄* E_(f) 1988 E_(1b)E₂E₃E₄ E_(v)E_(vi) E₄* E_(f) 1989 E_(1a)E₂E_(i)E₄ E_(v)E_(vi) E₄* E_(f) 1990 E_(1b)E₂E_(i)E₄ E_(v)E_(vi) E₄* E_(f) 1991 E_(1a)E₂E_(ii)E₄ E_(v)E_(vi) E₄* E_(f) 1992 E_(1b)E₂E_(ii)E₄ E_(v)E_(vi) E₄* E_(f) 1993 E_(1a)E₂E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* E_(f) 1994 E_(1b)E₂E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* E_(f) 1995 E_(1a)E₂E₃E_(i)E₄ E_(v)E_(vi) E₄* E_(f) 1996 E_(1b)E₂E₃E_(i)E₄ E_(v)E_(vi) E₄* E_(f) 1997 E_(1a)E₂E₃E_(ii)E₄ E_(v)E_(vi) E₄* E_(f) 1998 E_(1b)E₂E₃E_(ii)E₄ E_(v)E_(vi) E₄* E_(f) 1999 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* E_(f) 2000 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* E_(f) 2001 E_(1a)E₂E_(iii) E_(v)E_(vi) E₄* E_(f) 2002 E_(1b)E₂E_(iii) E_(v)E_(vi) E₄* E_(f) 2003 E_(1a)E₂E₃E_(iii) E_(v)E_(vi) E₄* E_(f) 2004 E_(1b)E₂E₃E_(iii) E_(v)E_(vi) E₄* E_(f) 2005 E_(1a)E₂E_(iii)E₄ E_(v)E_(vi) E₄* E_(f) 2006 E_(1b)E₂E_(iii)E₄ E_(v)E_(vi) E₄* E_(f) 2007 E_(1a)E₂E₃E_(iii)E₄ E_(v)E_(vi) E₄* E_(f) 2008 E_(1b)E₂E₃E_(iii)E₄ E_(v)E_(vi) E₄* E_(f) 2009 E_(1a)E₂E_(iv) E_(v)E_(vi) E₄* E_(f) 2010 E_(1b)E₂E_(iv) E_(v)E_(vi) E₄* E_(f) 2011 E_(1a)E₂E₃E_(iv) E_(v)E_(vi) E₄* E_(f) 2012 E_(1b)E₂E₃E_(iv) E_(v)E_(vi) E₄* E_(f) 2013 E_(1a)E₂E_(iv)E₄ E_(v)E_(vi) E₄* E_(f) 2014 E_(1b)E₂E_(iv)E₄ E_(v)E_(vi) E₄* E_(f) 2015 E_(1a)E₂E₃E_(iv)E₄ E_(v)E_(vi) E₄* E_(f) 2016 E_(1b)E₂E₃E_(iv)E₄ E_(v)E_(vi) E₄* E_(f) 2017 E_(1a)E₂ E_(v)E_(vi) E₅ E_(f) 2018 E_(1b)E₂ E_(v)E_(vi) E₅ E_(f) 2019 E_(1a)E₂E₃ E_(v)E_(vi) E₅ E_(f) 2020 E_(1b)E₂E₃ E_(v)E_(vi) E₅ E_(f) 2021 E_(1a)E₂E_(i) E_(v)E_(vi) E₅ E_(f) 2022 E_(1b)E₂E_(i) E_(v)E_(vi) E₅ E_(f) 2023 E_(1a)E₂E_(ii) E_(v)E_(vi) E₅ E_(f) 2024 E_(1b)E₂E_(ii) E_(v)E_(vi) E₅ E_(f) 2025 E_(1a)E₂E_(ii)E_(iib) E_(v)E_(vi) E₅ E_(f) 2026 E_(1b)E₂E_(ii)E_(iib) E_(v)E_(vi) E₅ E_(f) 2027 E_(1a)E₂E₃E_(i) E_(v)E_(vi) E₅ E_(f) 2028 E_(1b)E₂E₃E_(i) E_(v)E_(vi) E₅ E_(f) 2029 E_(1a)E₂E₃E_(ii) E_(v)E_(vi) E₅ E_(f) 2030 E_(1b)E₂E₃E_(ii) E_(v)E_(vi) E₅ E_(f) 2031 E_(1a)E₂E₃E_(ii)E_(iib) E_(v)E_(vi) E₅ E_(f) 2032 E_(1b)E₂E₃E_(ii)E_(iib) E_(v)E_(vi) E₅ E_(f) 2033 E_(1a)E₂E₄ E_(v)E_(vi) E₅ E_(f) 2034 E_(1b)E₂E₄ E_(v)E_(vi) E₅ E_(f) 2035 E_(1a)E₂E₃E₄ E_(v)E_(vi) E₅ E_(f) 2036 E_(1b)E₂E₃E₄ E_(v)E_(vi) E₅ E_(f) 2037 E_(1a)E₂E_(i)E₄ E_(v)E_(vi) E₅ E_(f) 2038 E_(1b)E₂E_(i)E₄ E_(v)E_(vi) E₅ E_(f) 2039 E_(1a)E₂E_(ii)E₄ E_(v)E_(vi) E₅ E_(f) 2040 E_(1b)E₂E_(ii)E₄ E_(v)E_(vi) E₅ E_(f) 2041 E_(1a)E₂E_(ii)E_(iib)E₄ E_(v)E_(vi) E₅ E_(f) 2042 E_(1b)E₂E_(ii)E_(iib)E₄ E_(v)E_(vi) E₅ E_(f) 2043 E_(1a)E₂E₃E_(i)E₄ E_(v)E_(vi) E₅ E_(f) 2044 E_(1b)E₂E₃E_(i)E₄ E_(v)E_(vi) E₅ E_(f) 2045 E_(1a)E₂E₃E_(ii)E₄ E_(v)E_(vi) E₅ E_(f) 2046 E_(1b)E₂E₃E_(ii)E₄ E_(v)E_(vi) E₅ E_(f) 2047 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E_(v)E_(vi) E₅ E_(f) 2048 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E_(v)E_(vi) E₅ E_(f) 2049 E_(1a)E₂E_(iii) E_(v)E_(vi) E₅ E_(f) 2050 E_(1b)E₂E_(iii) E_(v)E_(vi) E₅ E_(f) 2051 E_(1a)E₂E₃E_(iii) E_(v)E_(vi) E₅ E_(f) 2052 E_(1b)E₂E₃E_(iii) E_(v)E_(vi) E₅ E_(f) 2053 E_(1a)E₂E_(iii)E₄ E_(v)E_(vi) E₅ E_(f) 2054 E_(1b)E₂E_(iii)E₄ E_(v)E_(vi) E₅ E_(f) 2055 E_(1a)E₂E₃E_(iii)E₄ E_(v)E_(vi) E₅ E_(f) 2056 E_(1b)E₂E₃E_(iii)E₄ E_(v)E_(vi) E₅ E_(f) 2057 E_(1a)E₂E_(iv) E_(v)E_(vi) E₅ E_(f) 2058 E_(1b)E₂E_(iv) E_(v)E_(vi) E₅ E_(f) 2059 E_(1a)E₂E₃E_(iv) E_(v)E_(vi) E₅ E_(f) 2060 E_(1b)E₂E₃E_(iv) E_(v)E_(vi) E₅ E_(f) 2061 E_(1a)E₂E_(iv)E₄ E_(v)E_(vi) E₅ E_(f) 2062 E_(1b)E₂E_(iv)E₄ E_(v)E_(vi) E₅ E_(f) 2063 E_(1a)E₂E₃E_(iv)E₄ E_(v)E_(vi) E₅ E_(f) 2064 E_(1b)E₂E₃E_(iv)E₄ E_(v)E_(vi) E₅ E_(f) 2065 E_(1a)E₂ E_(v)E_(vi) E₄*E₅ E_(f) 2066 E_(1b)E₂ E_(v)E_(vi) E₄*E₅ E_(f) 2067 E_(1a)E₂E₃ E_(v)E_(vi) E₄*E₅ E_(f) 2068 E_(1b)E₂E₃ E_(v)E_(vi) E₄*E₅ E_(f) 2069 E_(1a)E₂E_(i) E_(v)E_(vi) E₄*E₅ E_(f) 2070 E_(1b)E₂E_(i) E_(v)E_(vi) E₄*E₅ E_(f) 2071 E_(1a)E₂E_(ii) E_(v)E_(vi) E₄*E₅ E_(f) 2072 E_(1b)E₂E_(ii) E_(v)E_(vi) E₄*E₅ E_(f) 2073 E_(1a)E₂E_(ii)E_(iib) E_(v)E_(vi) E₄*E₅ E_(f) 2074 E_(1b)E₂E_(ii)E_(iib) E_(v)E_(vi) E₄*E₅ E_(f) 2075 E_(1a)E₂E₃E_(i) E_(v)E_(vi) E₄*E₅ E_(f) 2076 E_(1b)E₂E₃E_(i) E_(v)E_(vi) E₄*E₅ E_(f) 2077 E_(1a)E₂E₃E_(ii) E_(v)E_(vi) E₄*E₅ E_(f) 2078 E_(1b)E₂E₃E_(ii) E_(v)E_(vi) E₄*E₅ E_(f) 2079 E_(1a)E₂E₃E_(ii)E_(iib) E_(v)E_(vi) E₄*E₅ E_(f) 2080 E_(1b)E₂E₃E_(ii)E_(iib) E_(v)E_(vi) E₄*E₅ E_(f) 2081 E_(1a)E₂E₄ E_(v)E_(vi) E₄*E₅ E_(f) 2082 E_(1b)E₂E₄ E_(v)E_(vi) E₄*E₅ E_(f) 2083 E_(1a)E₂E₃E₄ E_(v)E_(vi) E₄*E₅ E_(f) 2084 E_(1b)E₂E₃E₄ E_(v)E_(vi) E₄*E₅ E_(f) 2085 E_(1a)E₂E_(i)E₄ E_(v)E_(vi) E₄*E₅ E_(f) 2086 E_(1b)E₂E_(i)E₄ E_(v)E_(vi) E₄*E₅ E_(f) 2087 E_(1a)E₂E_(ii)E₄ E_(v)E_(vi) E₄*E₅ E_(f) 2088 E_(1b)E₂E_(ii)E₄ E_(v)E_(vi) E₄*E₅ E_(f) 2089 E_(1a)E₂E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄*E₅ E_(f) 2090 E_(1b)E₂E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄*E₅ E_(f) 2091 E_(1a)E₂E₃E_(i)E₄ E_(v)E_(vi) E₄*E₅ E_(f) 2092 E_(1b)E₂E₃E_(i)E₄ E_(v)E_(vi) E₄*E₅ E_(f) 2093 E_(1a)E₂E₃E_(ii)E₄ E_(v)E_(vi) E₄*E₅ E_(f) 2094 E_(1b)E₂E₃E_(ii)E₄ E_(v)E_(vi) E₄*E₅ E_(f) 2095 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄*E₅ E_(f) 2096 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄*E₅ E_(f) 2097 E_(1a)E₂E_(iii) E_(v)E_(vi) E₄*E₅ E_(f) 2098 E_(1b)E₂E_(iii) E_(v)E_(vi) E₄*E₅ E_(f) 2099 E_(1a)E₂E₃E_(iii) E_(v)E_(vi) E₄*E₅ E_(f) 2100 E_(1b)E₂E₃E_(iii) E_(v)E_(vi) E₄*E₅ E_(f) 2101 E_(1a)E₂E_(iii)E₄ E_(v)E_(vi) E₄*E₅ E_(f) 2102 E_(1b)E₂E_(iii)E₄ E_(v)E_(vi) E₄*E₅ E_(f) 2103 E_(1a)E₂E₃E_(iii)E₄ E_(v)E_(vi) E₄*E₅ E_(f) 2104 E_(1b)E₂E₃E_(iii)E₄ E_(v)E_(vi) E₄*E₅ E_(f) 2105 E_(1a)E₂E_(iv) E_(v)E_(vi) E₄*E₅ E_(f) 2106 E_(1b)E₂E_(iv) E_(v)E_(vi) E₄*E₅ E_(f) 2107 E_(1a)E₂E₃E_(iv) E_(v)E_(vi) E₄*E₅ E_(f) 2108 E_(1b)E₂E₃E_(iv) E_(v)E_(vi) E₄*E₅ E_(f) 2109 E_(1a)E₂E_(iv)E₄ E_(v)E_(vi) E₄*E₅ E_(f) 2110 E_(1b)E₂E_(iv)E₄ E_(v)E_(vi) E₄*E₅ E_(f) 2111 E_(1a)E₂E₃E_(iv)E₄ E_(v)E_(vi) E₄*E₅ E_(f) 2112 E_(1b)E₂E₃E_(iv)E₄ E_(v)E_(vi) E₄*E₅ E_(f) 2113 E_(1a)E₂ AlkLE_(v)E_(vi) E_(f) 2114 E_(1b)E₂ AlkLE_(v)E_(vi) E_(f) 2115 E_(1a)E₂E₃ AlkLE_(v)E_(vi) E_(f) 2116 E_(1b)E₂E₃ AlkLE_(v)E_(vi) E_(f) 2117 E_(1a)E₂E_(i) AlkLE_(v)E_(vi) E_(f) 2118 E_(1b)E₂E_(i) AlkLE_(v)E_(vi) E_(f) 2119 E_(1a)E₂E_(ii) AlkLE_(v)E_(vi) E_(f) 2120 E_(1b)E₂E_(ii) AlkLE_(v)E_(vi) E_(f) 2121 E_(1a)E₂E_(ii)E_(iib) AlkLE_(v)E_(vi) E_(f) 2122 E_(1b)E₂E_(ii)E_(iib) AlkLE_(v)E_(vi) E_(f) 2123 E_(1a)E₂E₃E_(i) AlkLE_(v)E_(vi) E_(f) 2124 E_(1b)E₂E₃E_(i) AlkLE_(v)E_(vi) E_(f) 2125 E_(1a)E₂E₃E_(ii) AlkLE_(v)E_(vi) E_(f) 2126 E_(1b)E₂E₃E_(ii) AlkLE_(v)E_(vi) E_(f) 2127 E_(1a)E₂E₃E_(ii)E_(iib) AlkLE_(v)E_(vi) E_(f) 2128 E_(1b)E₂E₃E_(ii)E_(iib) AlkLE_(v)E_(vi) E_(f) 2129 E_(1a)E₂E₄ AlkLE_(v)E_(vi) E_(f) 2130 E_(1b)E₂E₄ AlkLE_(v)E_(vi) E_(f) 2131 E_(1a)E₂E₃E₄ AlkLE_(v)E_(vi) E_(f) 2132 E_(1b)E₂E₃E₄ AlkLE_(v)E_(vi) E_(f) 2133 E_(1a)E₂E_(i)E₄ AlkLE_(v)E_(vi) E_(f) 2134 E_(1b)E₂E_(i)E₄ AlkLE_(v)E_(vi) E_(f) 2135 E_(1a)E₂E_(ii)E₄ AlkLE_(v)E_(vi) E_(f) 2136 E_(1b)E₂E_(ii)E₄ AlkLE_(v)E_(vi) E_(f) 2137 E_(1a)E₂E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E_(f) 2138 E_(1b)E₂E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E_(f) 2139 E_(1a)E₂E₃E_(i)E₄ AlkLE_(v)E_(vi) E_(f) 2140 E_(1b)E₂E₃E_(i)E₄ AlkLE_(v)E_(vi) E_(f) 2141 E_(1a)E₂E₃E_(ii)E₄ AlkLE_(v)E_(vi) E_(f) 2142 E_(1b)E₂E₃E_(ii)E₄ AlkLE_(v)E_(vi) E_(f) 2143 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E_(f) 2144 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E_(f) 2145 E_(1a)E₂E_(iii) AlkLE_(v)E_(vi) E_(f) 2146 E_(1b)E₂E_(iii) AlkLE_(v)E_(vi) E_(f) 2147 E_(1a)E₂E₃E_(iii) AlkLE_(v)E_(vi) E_(f) 2148 E_(1b)E₂E₃E_(iii) AlkLE_(v)E_(vi) E_(f) 2149 E_(1a)E₂E_(iii)E₄ AlkLE_(v)E_(vi) E_(f) 2150 E_(1b)E₂E_(iii)E₄ AlkLE_(v)E_(vi) E_(f) 2151 E_(1a)E₂E₃E_(iii)E₄ AlkLE_(v)E_(vi) E_(f) 2152 E_(1b)E₂E₃E_(iii)E₄ AlkLE_(v)E_(vi) E_(f) 2153 E_(1a)E₂E_(iv) AlkLE_(v)E_(vi) E_(f) 2154 E_(1b)E₂E_(iv) AlkLE_(v)E_(vi) E_(f) 2155 E_(1a)E₂E₃E_(iv) AlkLE_(v)E_(vi) E_(f) 2156 E_(1b)E₂E₃E_(iv) AlkLE_(v)E_(vi) E_(f) 2157 E_(1a)E₂E_(iv)E₄ AlkLE_(v)E_(vi) E_(f) 2158 E_(1b)E₂E_(iv)E₄ AlkLE_(v)E_(vi) E_(f) 2159 E_(1a)E₂E₃E_(iv)E₄ AlkLE_(v)E_(vi) E_(f) 2160 E_(1b)E₂E₃E_(iv)E₄ AlkLE_(v)E_(vi) E_(f) 2161 E_(1a)E₂ AlkLE_(v)E_(vi) E₄* E_(f) 2162 E_(1b)E₂ AlkLE_(v)E_(vi) E₄* E_(f) 2163 E_(1a)E₂E₃ AlkLE_(v)E_(vi) E₄* E_(f) 2164 E_(1b)E₂E₃ AlkLE_(v)E_(vi) E₄* E_(f) 2165 E_(1a)E₂E_(i) AlkLE_(v)E_(vi) E₄* E_(f) 2166 E_(1b)E₂E_(i) AlkLE_(v)E_(vi) E₄* E_(f) 2167 E_(1a)E₂E_(ii) AlkLE_(v)E_(vi) E₄* E_(f) 2168 E_(1b)E₂E_(ii) AlkLE_(v)E_(vi) E₄* E_(f) 2169 E_(1a)E₂E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* E_(f) 2170 E_(1b)E₂E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* E_(f) 2171 E_(1a)E₂E₃E_(i) AlkLE_(v)E_(vi) E₄* E_(f) 2172 E_(1b)E₂E₃E_(i) AlkLE_(v)E_(vi) E₄* E_(f) 2173 E_(1a)E₂E₃E_(ii) AlkLE_(v)E_(vi) E₄* E_(f) 2174 E_(1b)E₂E₃E_(ii) AlkLE_(v)E_(vi) E₄* E_(f) 2175 E_(1a)E₂E₃E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* E_(f) 2176 E_(1b)E₂E₃E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* E_(f) 2177 E_(1a)E₂E₄ AlkLE_(v)E_(vi) E₄* E_(f) 2178 E_(1b)E₂E₄ AlkLE_(v)E_(vi) E₄* E_(f) 2179 E_(1a)E₂E₃E₄ AlkLE_(v)E_(vi) E₄* E_(f) 2180 E_(1b)E₂E₃E₄ AlkLE_(v)E_(vi) E₄* E_(f) 2181 E_(1a)E₂E_(i)E₄ AlkLE_(v)E_(vi) E₄* E_(f) 2182 E_(1b)E₂E_(i)E₄ AlkLE_(v)E_(vi) E₄* E_(f) 2183 E_(1a)E₂E_(ii)E₄ AlkLE_(v)E_(vi) E₄* E_(f) 2184 E_(1b)E₂E_(ii)E₄ AlkLE_(v)E_(vi) E₄* E_(f) 2185 E_(1a)E₂E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* E_(f) 2186 E_(1b)E₂E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* E_(f) 2187 E_(1a)E₂E₃E_(i)E₄ AlkLE_(v)E_(vi) E₄* E_(f) 2188 E_(1b)E₂E₃E_(i)E₄ AlkLE_(v)E_(vi) E₄* E_(f) 2189 E_(1a)E₂E₃E_(ii)E₄ AlkLE_(v)E_(vi) E₄* E_(f) 2190 E_(1b)E₂E₃E_(ii)E₄ AlkLE_(v)E_(vi) E₄* E_(f) 2191 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* E_(f) 2192 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* E_(f) 2193 E_(1a)E₂E_(iii) AlkLE_(v)E_(vi) E₄* E_(f) 2194 E_(1b)E₂E_(iii) AlkLE_(v)E_(vi) E₄* E_(f) 2195 E_(1a)E₂E₃E_(iii) AlkLE_(v)E_(vi) E₄* E_(f) 2196 E_(1b)E₂E₃E_(iii) AlkLE_(v)E_(vi) E₄* E_(f) 2197 E_(1a)E₂E_(iii)E₄ AlkLE_(v)E_(vi) E₄* E_(f) 2198 E_(1b)E₂E_(iii)E₄ AlkLE_(v)E_(vi) E₄* E_(f) 2199 E_(1a)E₂E₃E_(iii)E₄ AlkLE_(v)E_(vi) E₄* E_(f) 2200 E_(1b)E₂E₃E_(iii)E₄ AlkLE_(v)E_(vi) E₄* E_(f) 2201 E_(1a)E₂E_(iv) AlkLE_(v)E_(vi) E₄* E_(f) 2202 E_(1b)E₂E_(iv) AlkLE_(v)E_(vi) E₄* E_(f) 2203 E_(1a)E₂E₃E_(iv) AlkLE_(v)E_(vi) E₄* E_(f) 2204 E_(1b)E₂E₃E_(iv) AlkLE_(v)E_(vi) E₄* E_(f) 2205 E_(1a)E₂E_(iv)E₄ AlkLE_(v)E_(vi) E₄* E_(f) 2206 E_(1b)E₂E_(iv)E₄ AlkLE_(v)E_(vi) E₄* E_(f) 2207 E_(1a)E₂E₃E_(iv)E₄ AlkLE_(v)E_(vi) E₄* E_(f) 2208 E_(1b)E₂E₃E_(iv)E₄ AlkLE_(v)E_(vi) E₄* E_(f) 2209 E_(1a)E₂ AlkLE_(v)E_(vi) E₅ E_(f) 2210 E_(1b)E₂ AlkLE_(v)E_(vi) E₅ E_(f) 2211 E_(1a)E₂E₃ AlkLE_(v)E_(vi) E₅ E_(f) 2212 E_(1b)E₂E₃ AlkLE_(v)E_(vi) E₅ E_(f) 2213 E_(1a)E₂E_(i) AlkLE_(v)E_(vi) E₅ E_(f) 2214 E_(1b)E₂E_(i) AlkLE_(v)E_(vi) E₅ E_(f) 2215 E_(1a)E₂E_(ii) AlkLE_(v)E_(vi) E₅ E_(f) 2216 E_(1b)E₂E_(ii) AlkLE_(v)E_(vi) E₅ E_(f) 2217 E_(1a)E₂E_(ii)E_(iib) AlkLE_(v)E_(vi) E₅ E_(f) 2218 E_(1b)E₂E_(ii)E_(iib) AlkLE_(v)E_(vi) E₅ E_(f) 2219 E_(1a)E₂E₃E_(i) AlkLE_(v)E_(vi) E₅ E_(f) 2220 E_(1b)E₂E₃E_(i) AlkLE_(v)E_(vi) E₅ E_(f) 2221 E_(1a)E₂E₃E_(ii) AlkLE_(v)E_(vi) E₅ E_(f) 2222 E_(1b)E₂E₃E_(ii) AlkLE_(v)E_(vi) E₅ E_(f) 2223 E_(1a)E₂E₃E_(ii)E_(iib) AlkLE_(v)E_(vi) E₅ E_(f) 2224 E_(1b)E₂E₃E_(ii)E_(iib) AlkLE_(v)E_(vi) E₅ E_(f) 2225 E_(1a)E₂E₄ AlkLE_(v)E_(vi) E₅ E_(f) 2226 E_(1b)E₂E₄ AlkLE_(v)E_(vi) E₅ E_(f) 2227 E_(1a)E₂E₃E₄ AlkLE_(v)E_(vi) E₅ E_(f) 2228 E_(1b)E₂E₃E₄ AlkLE_(v)E_(vi) E₅ E_(f) 2229 E_(1a)E₂E_(i)E₄ AlkLE_(v)E_(vi) E₅ E_(f) 2230 E_(1b)E₂E_(i)E₄ AlkLE_(v)E_(vi) E₅ E_(f) 2231 E_(1a)E₂E_(ii)E₄ AlkLE_(v)E_(vi) E₅ E_(f) 2232 E_(1b)E₂E_(ii)E₄ AlkLE_(v)E_(vi) E₅ E_(f) 2233 E_(1a)E₂E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₅ E_(f) 2234 E_(1b)E₂E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₅ E_(f) 2235 E_(1a)E₂E₃E_(i)E₄ AlkLE_(v)E_(vi) E₅ E_(f) 2236 E_(1b)E₂E₃E_(i)E₄ AlkLE_(v)E_(vi) E₅ E_(f) 2237 E_(1a)E₂E₃E_(ii)E₄ AlkLE_(v)E_(vi) E₅ E_(f) 2238 E_(1b)E₂E₃E_(ii)E₄ AlkLE_(v)E_(vi) E₅ E_(f) 2239 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₅ E_(f) 2240 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₅ E_(f) 2241 E_(1a)E₂E_(iii) AlkLE_(v)E_(vi) E₅ E_(f) 2242 E_(1b)E₂E_(iii) AlkLE_(v)E_(vi) E₅ E_(f) 2243 E_(1a)E₂E₃E_(iii) AlkLE_(v)E_(vi) E₅ E_(f) 2244 E_(1b)E₂E₃E_(iii) AlkLE_(v)E_(vi) E₅ E_(f) 2245 E_(1a)E₂E_(iii)E₄ AlkLE_(v)E_(vi) E₅ E_(f) 2246 E_(1b)E₂E_(iii)E₄ AlkLE_(v)E_(vi) E₅ E_(f) 2247 E_(1a)E₂E₃E_(iii)E₄ AlkLE_(v)E_(vi) E₅ E_(f) 2248 E_(1b)E₂E₃E_(iii)E₄ AlkLE_(v)E_(vi) E₅ E_(f) 2249 E_(1a)E₂E_(iv) AlkLE_(v)E_(vi) E₅ E_(f) 2250 E_(1b)E₂E_(iv) AlkLE_(v)E_(vi) E₅ E_(f) 2251 E_(1a)E₂E₃E_(iv) AlkLE_(v)E_(vi) E₅ E_(f) 2252 E_(1b)E₂E₃E_(iv) AlkLE_(v)E_(vi) E₅ E_(f) 2253 E_(1a)E₂E_(iv)E₄ AlkLE_(v)E_(vi) E₅ E_(f) 2254 E_(1b)E₂E_(iv)E₄ AlkLE_(v)E_(vi) E₅ E_(f) 2255 E_(1a)E₂E₃E_(iv)E₄ AlkLE_(v)E_(vi) E₅ E_(f) 2256 E_(1b)E₂E₃E_(iv)E₄ AlkLE_(v)E_(vi) E₅ E_(f) 2257 E_(1a)E₂ AlkLE_(v)E_(vi) E₄*E₅ E_(f) 2258 E_(1b)E₂ AlkLE_(v)E_(vi) E₄*E₅ E_(f) 2259 E_(1a)E₂E₃ AlkLE_(v)E_(vi) E₄*E₅ E_(f) 2260 E_(1b)E₂E₃ AlkLE_(v)E_(vi) E₄*E₅ E_(f) 2261 E_(1a)E₂E_(i) AlkLE_(v)E_(vi) E₄*E₅ E_(f) 2262 E_(1b)E₂E_(i) AlkLE_(v)E_(vi) E₄*E₅ E_(f) 2263 E_(1a)E₂E_(ii) AlkLE_(v)E_(vi) E₄*E₅ E_(f) 2264 E_(1b)E₂E_(ii) AlkLE_(v)E_(vi) E₄*E₅ E_(f) 2265 E_(1a)E₂E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄*E₅ E_(f) 2266 E_(1b)E₂E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄*E₅ E_(f) 2267 E_(1a)E₂E₃E_(i) AlkLE_(v)E_(vi) E₄*E₅ E_(f) 2268 E_(1b)E₂E₃E_(i) AlkLE_(v)E_(vi) E₄*E₅ E_(f) 2269 E_(1a)E₂E₃E_(ii) AlkLE_(v)E_(vi) E₄*E₅ E_(f) 2270 E_(1b)E₂E₃E_(ii) AlkLE_(v)E_(vi) E₄*E₅ E_(f) 2271 E_(1a)E₂E₃E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄*E₅ E_(f) 2272 E_(1b)E₂E₃E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄*E₅ E_(f) 2273 E_(1a)E₂E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(f) 2274 E_(1b)E₂E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(f) 2275 E_(1a)E₂E₃E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(f) 2276 E_(1b)E₂E₃E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(f) 2277 E_(1a)E₂E_(i)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(f) 2278 E_(1b)E₂E_(i)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(f) 2279 E_(1a)E₂E_(ii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(f) 2280 E_(1b)E₂E_(ii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(f) 2281 E_(1a)E₂E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(f) 2282 E_(1b)E₂E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(f) 2283 E_(1a)E₂E₃E_(i)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(f) 2284 E_(1b)E₂E₃E_(i)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(f) 2285 E_(1a)E₂E₃E_(ii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(f) 2286 E_(1b)E₂E₃E_(ii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(f) 2287 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(f) 2288 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(f) 2289 E_(1a)E₂E_(iii) AlkLE_(v)E_(vi) E₄*E₅ E_(f) 2290 E_(1b)E₂E_(iii) AlkLE_(v)E_(vi) E₄*E₅ E_(f) 2291 E_(1a)E₂E₃E_(iii) AlkLE_(v)E_(vi) E₄*E₅ E_(f) 2292 E_(1b)E₂E₃E_(iii) AlkLE_(v)E_(vi) E₄*E₅ E_(f) 2293 E_(1a)E₂E_(iii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(f) 2294 E_(1b)E₂E_(iii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(f) 2295 E_(1a)E₂E₃E_(iii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(f) 2296 E_(1b)E₂E₃E_(iii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(f) 2297 E_(1a)E₂E_(iv) AlkLE_(v)E_(vi) E₄*E₅ E_(f) 2298 E_(1b)E₂E_(iv) AlkLE_(v)E_(vi) E₄*E₅ E_(f) 2299 E_(1a)E₂E₃E_(iv) AlkLE_(v)E_(vi) E₄*E₅ E_(f) 2300 E_(1b)E₂E₃E_(iv) AlkLE_(v)E_(vi) E₄*E₅ E_(f) 2301 E_(1a)E₂E_(iv)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(f) 2302 E_(1b)E₂E_(iv)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(f) 2303 E_(1a)E₂E₃E_(iv)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(f) 2304 E_(1b)E₂E₃E_(iv)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(f) 2305 E_(1a)E₂ E_(vii) 2306 E_(1b)E₂ E_(vii) 2307 E_(1a)E₂E₃ E_(vii) 2308 E_(1b)E₂E₃ E_(vii) 2309 E_(1a)E₂E_(i) E_(vii) 2310 E_(1b)E₂E_(i) E_(vii) 2311 E_(1a)E₂E_(ii) E_(vii) 2312 E_(1b)E₂E_(ii) E_(vii) 2313 E_(1a)E₂E_(ii)E_(iib) E_(vii) 2314 E_(1b)E₂E_(ii)E_(iib) E_(vii) 2315 E_(1a)E₂E₃E_(i) E_(vii) 2316 E_(1b)E₂E₃E_(i) E_(vii) 2317 E_(1a)E₂E₃E_(ii) E_(vii) 2318 E_(1b)E₂E₃E_(ii) E_(vii) 2319 E_(1a)E₂E₃E_(ii)E_(iib) E_(vii) 2320 E_(1b)E₂E₃E_(ii)E_(iib) E_(vii) 2321 E_(1a)E₂E₄ E_(vii) 2322 E_(1b)E₂E₄ E_(vii) 2323 E_(1a)E₂E₃E₄ E_(vii) 2324 E_(1b)E₂E₃E₄ E_(vii) 2325 E_(1a)E₂E_(i)E₄ E_(vii) 2326 E_(1b)E₂E_(i)E₄ E_(vii) 2327 E_(1a)E₂E_(ii)E₄ E_(vii) 2328 E_(1b)E₂E_(ii)E₄ E_(vii) 2329 E_(1a)E₂E_(ii)E_(iib)E₄ E_(vii) 2330 E_(1b)E₂E_(ii)E_(iib)E₄ E_(vii) 2331 E_(1a)E₂E₃E_(i)E₄ E_(vii) 2332 E_(1b)E₂E₃E_(i)E₄ E_(vii) 2333 E_(1a)E₂E₃E_(ii)E₄ E_(vii) 2334 E_(1b)E₂E₃E_(ii)E₄ E_(vii) 2335 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E_(vii) 2336 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E_(vii) 2337 E_(1a)E₂E_(iii) E_(vii) 2338 E_(1b)E₂E_(iii) E_(vii) 2339 E_(1a)E₂E₃E_(iii) E_(vii) 2340 E_(1b)E₂E₃E_(iii) E_(vii) 2341 E_(1a)E₂E_(iii)E₄ E_(vii) 2342 E_(1b)E₂E_(iii)E₄ E_(vii) 2343 E_(1a)E₂E₃E_(iii)E₄ E_(vii) 2344 E_(1b)E₂E₃E_(iii)E₄ E_(vii) 2345 E_(1a)E₂E_(iv) E_(vii) 2346 E_(1b)E₂E_(iv) E_(vii) 2347 E_(1a)E₂E₃E_(iv) E_(vii) 2348 E_(1b)E₂E₃E_(iv) E_(vii) 2349 E_(1a)E₂E_(iv)E₄ E_(vii) 2350 E_(1b)E₂E_(iv)E₄ E_(vii) 2351 E_(1a)E₂E₃E_(iv)E₄ E_(vii) 2352 E_(1b)E₂E₃E_(iv)E₄ E_(vii) 2353 E_(1a)E₂ E_(vii) E₄* 2354 E_(1b)E₂ E_(vii) E₄* 2355 E_(1a)E₂E₃ E_(vii) E₄* 2356 E_(1b)E₂E₃ E_(vii) E₄* 2357 E_(1a)E₂E_(i) E_(vii) E₄* 2358 E_(1b)E₂E_(i) E_(vii) E₄* 2359 E_(1a)E₂E_(ii) E_(vii) E₄* 2360 E_(1b)E₂E_(ii) E_(vii) E₄* 2361 E_(1a)E₂E_(ii)E_(iib) E_(vii) E₄* 2362 E_(1b)E₂E_(ii)E_(iib) E_(vii) E₄* 2363 E_(1a)E₂E₃E_(i) E_(vii) E₄* 2364 E_(1b)E₂E₃E_(i) E_(vii) E₄* 2365 E_(1a)E₂E₃E_(ii) E_(vii) E₄* 2366 E_(1b)E₂E₃E_(ii) E_(vii) E₄* 2367 E_(1a)E₂E₃E_(ii)E_(iib) E_(vii) E₄* 2368 E_(1b)E₂E₃E_(ii)E_(iib) E_(vii) E₄* 2369 E_(1a)E₂E₄ E_(vii) E₄* 2370 E_(1b)E₂E₄ E_(vii) E₄* 2371 E_(1a)E₂E₃E₄ E_(vii) E₄* 2372 E_(1b)E₂E₃E₄ E_(vii) E₄* 2373 E_(1a)E₂E_(i)E₄ E_(vii) E₄* 2374 E_(1b)E₂E_(i)E₄ E_(vii) E₄* 2375 E_(1a)E₂E_(ii)E₄ E_(vii) E₄* 2376 E_(1b)E₂E_(ii)E₄ E_(vii) E₄* 2377 E_(1a)E₂E_(ii)E_(iib)E₄ E_(vii) E₄* 2378 E_(1b)E₂E_(ii)E_(iib)E₄ E_(vii) E₄* 2379 E_(1a)E₂E₃E_(i)E₄ E_(vii) E₄* 2380 E_(1b)E₂E₃E_(i)E₄ E_(vii) E₄* 2381 E_(1a)E₂E₃E_(ii)E₄ E_(vii) E₄* 2382 E_(1b)E₂E₃E_(ii)E₄ E_(vii) E₄* 2383 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E_(vii) E₄* 2384 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E_(vii) E₄* 2385 E_(1a)E₂E_(iii) E_(vii) E₄* 2386 E_(1b)E₂E_(iii) E_(vii) E₄* 2387 E_(1a)E₂E₃E_(iii) E_(vii) E₄* 2388 E_(1b)E₂E₃E_(iii) E_(vii) E₄* 2389 E_(1a)E₂E_(iii)E₄ E_(vii) E₄* 2390 E_(1b)E₂E_(iii)E₄ E_(vii) E₄* 2391 E_(1a)E₂E₃E_(iii)E₄ E_(vii) E₄* 2392 E_(1b)E₂E₃E_(iii)E₄ E_(vii) E₄* 2393 E_(1a)E₂E_(iv) E_(vii) E₄* 2394 E_(1b)E₂E_(iv) E_(vii) E₄* 2395 E_(1a)E₂E₃E_(iv) E_(vii) E₄* 2396 E_(1b)E₂E₃E_(iv) E_(vii) E₄* 2397 E_(1a)E₂E_(iv)E₄ E_(vii) E₄* 2398 E_(1b)E₂E_(iv)E₄ E_(vii) E₄* 2399 E_(1a)E₂E₃E_(iv)E₄ E_(vii) E₄* 2400 E_(1b)E₂E₃E_(iv)E₄ E_(vii) E₄* 2401 E_(1a)E₂ E_(vii) E₅ 2402 E_(1b)E₂ E_(vii) E₅ 2403 E_(1a)E₂E₃ E_(vii) E₅ 2404 E_(1b)E₂E₃ E_(vii) E₅ 2405 E_(1a)E₂E_(i) E_(vii) E₅ 2406 E_(1b)E₂E_(i) E_(vii) E₅ 2407 E_(1a)E₂E_(ii) E_(vii) E₅ 2408 E_(1b)E₂E_(ii) E_(vii) E₅ 2409 E_(1a)E₂E_(ii)E_(iib) E_(vii) E₅ 2410 E_(1b)E₂E_(ii)E_(iib) E_(vii) E₅ 2411 E_(1a)E₂E₃E_(i) E_(vii) E₅ 2412 E_(1b)E₂E₃E_(i) E_(vii) E₅ 2413 E_(1a)E₂E₃E_(ii) E_(vii) E₅ 2414 E_(1b)E₂E₃E_(ii) E_(vii) E₅ 2415 E_(1a)E₂E₃E_(ii)E_(iib) E_(vii) E₅ 2416 E_(1b)E₂E₃E_(ii)E_(iib) E_(vii) E₅ 2417 E_(1a)E₂E₄ E_(vii) E₅ 2418 E_(1b)E₂E₄ E_(vii) E₅ 2419 E_(1a)E₂E₃E₄ E_(vii) E₅ 2420 E_(1b)E₂E₃E₄ E_(vii) E₅ 2421 E_(1a)E₂E_(i)E₄ E_(vii) E₅ 2422 E_(1b)E₂E_(i)E₄ E_(vii) E₅ 2423 E_(1a)E₂E_(ii)E₄ E_(vii) E₅ 2424 E_(1b)E₂E_(ii)E₄ E_(vii) E₅ 2425 E_(1a)E₂E_(ii)E_(iib)E₄ E_(vii) E₅ 2426 E_(1b)E₂E_(ii)E_(iib)E₄ E_(vii) E₅ 2427 E_(1a)E₂E₃E_(i)E₄ E_(vii) E₅ 2428 E_(1b)E₂E₃E_(i)E₄ E_(vii) E₅ 2429 E_(1a)E₂E₃E_(ii)E₄ E_(vii) E₅ 2430 E_(1b)E₂E₃E_(ii)E₄ E_(vii) E₅ 2431 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E_(vii) E₅ 2432 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E_(vii) E₅ 2433 E_(1a)E₂E_(iii) E_(vii) E₅ 2434 E_(1b)E₂E_(iii) E_(vii) E₅ 2435 E_(1a)E₂E₃E_(iii) E_(vii) E₅ 2436 E_(1b)E₂E₃E_(iii) E_(vii) E₅ 2437 E_(1a)E₂E_(iii)E₄ E_(vii) E₅ 2438 E_(1b)E₂E_(iii)E₄ E_(vii) E₅ 2439 E_(1a)E₂E₃E_(iii)E₄ E_(vii) E₅ 2440 E_(1b)E₂E₃E_(iii)E₄ E_(vii) E₅ 2441 E_(1a)E₂E_(iv) E_(vii) E₅ 2442 E_(1b)E₂E_(iv) E_(vii) E₅ 2443 E_(1a)E₂E₃E_(iv) E_(vii) E₅ 2444 E_(1b)E₂E₃E_(iv) E_(vii) E₅ 2445 E_(1a)E₂E_(iv)E₄ E_(vii) E₅ 2446 E_(1b)E₂E_(iv)E₄ E_(vii) E₅ 2447 E_(1a)E₂E₃E_(iv)E₄ E_(vii) E₅ 2448 E_(1b)E₂E₃E_(iv)E₄ E_(vii) E₅ 2449 E_(1a)E₂ E_(vii) E₄*E₅ 2450 E_(1b)E₂ E_(vii) E₄*E₅ 2451 E_(1a)E₂E₃ E_(vii) E₄*E₅ 2452 E_(1b)E₂E₃ E_(vii) E₄*E₅ 2453 E_(1a)E₂E_(i) E_(vii) E₄*E₅ 2454 E_(1b)E₂E_(i) E_(vii) E₄*E₅ 2455 E_(1a)E₂E_(ii) E_(vii) E₄*E₅ 2456 E_(1b)E₂E_(ii) E_(vii) E₄*E₅ 2457 E_(1a)E₂E_(ii)E_(iib) E_(vii) E₄*E₅ 2458 E_(1b)E₂E_(ii)E_(iib) E_(vii) E₄*E₅ 2459 E_(1a)E₂E₃E_(i) E_(vii) E₄*E₅ 2460 E_(1b)E₂E₃E_(i) E_(vii) E₄*E₅ 2461 E_(1a)E₂E₃E_(ii) E_(vii) E₄*E₅ 2462 E_(1b)E₂E₃E_(ii) E_(vii) E₄*E₅ 2463 E_(1a)E₂E₃E_(ii)E_(iib) E_(vii) E₄*E₅ 2464 E_(1b)E₂E₃E_(ii)E_(iib) E_(vii) E₄*E₅ 2465 E_(1a)E₂E₄ E_(vii) E₄*E₅ 2466 E_(1b)E₂E₄ E_(vii) E₄*E₅ 2467 E_(1a)E₂E₃E₄ E_(vii) E₄*E₅ 2468 E_(1b)E₂E₃E₄ E_(vii) E₄*E₅ 2469 E_(1a)E₂E_(i)E₄ E_(vii) E₄*E₅ 2470 E_(1b)E₂E_(i)E₄ E_(vii) E₄*E₅ 2471 E_(1a)E₂E_(ii)E₄ E_(vii) E₄*E₅ 2472 E_(1b)E₂E_(ii)E₄ E_(vii) E₄*E₅ 2473 E_(1a)E₂E_(ii)E_(iib)E₄ E_(vii) E₄*E₅ 2474 E_(1b)E₂E_(ii)E_(iib)E₄ E_(vii) E₄*E₅ 2475 E_(1a)E₂E₃E_(i)E₄ E_(vii) E₄*E₅ 2476 E_(1b)E₂E₃E_(i)E₄ E_(vii) E₄*E₅ 2477 E_(1a)E₂E₃E_(ii)E₄ E_(vii) E₄*E₅ 2478 E_(1b)E₂E₃E_(ii)E₄ E_(vii) E₄*E₅ 2479 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E_(vii) E₄*E₅ 2480 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E_(vii) E₄*E₅ 2481 E_(1a)E₂E_(iii) E_(vii) E₄*E₅ 2482 E_(1b)E₂E_(iii) E_(vii) E₄*E₅ 2483 E_(1a)E₂E₃E_(iii) E_(vii) E₄*E₅ 2484 E_(1b)E₂E₃E_(iii) E_(vii) E₄*E₅ 2485 E_(1a)E₂E_(iii)E₄ E_(vii) E₄*E₅ 2486 E_(1b)E₂E_(iii)E₄ E_(vii) E₄*E₅ 2487 E_(1a)E₂E₃E_(iii)E₄ E_(vii) E₄*E₅ 2488 E_(1b)E₂E₃E_(iii)E₄ E_(vii) E₄*E₅ 2489 E_(1a)E₂E_(iv) E_(vii) E₄*E₅ 2490 E_(1b)E₂E_(iv) E_(vii) E₄*E₅ 2491 E_(1a)E₂E₃E_(iv) E_(vii) E₄*E₅ 2492 E_(1b)E₂E₃E_(iv) E_(vii) E₄*E₅ 2493 E_(1a)E₂E_(iv)E₄ E_(vii) E₄*E₅ 2494 E_(1b)E₂E_(iv)E₄ E_(vii) E₄*E₅ 2495 E_(1a)E₂E₃E_(iv)E₄ E_(vii) E₄*E₅ 2496 E_(1b)E₂E₃E_(iv)E₄ E_(vii) E₄*E₅ 2497 E_(1a)E₂ AlkLE_(vii) 2498 E_(1b)E₂ AlkLE_(vii) 2499 E_(1a)E₂E₃ AlkLE_(vii) 2500 E_(1b)E₂E₃ AlkLE_(vii) 2501 E_(1a)E₂E_(i) AlkLE_(vii) 2502 E_(1b)E₂E_(i) AlkLE_(vii) 2503 E_(1a)E₂E_(ii) AlkLE_(vii) 2504 E_(1b)E₂E_(ii) AlkLE_(vii) 2505 E_(1a)E₂E_(ii)E_(iib) AlkLE_(vii) 2506 E_(1b)E₂E_(ii)E_(iib) AlkLE_(vii) 2507 E_(1a)E₂E₃E_(i) AlkLE_(vii) 2508 E_(1b)E₂E₃E_(i) AlkLE_(vii) 2509 E_(1a)E₂E₃E_(ii) AlkLE_(vii) 2510 E_(1b)E₂E₃E_(ii) AlkLE_(vii) 2511 E_(1a)E₂E₃E_(ii)E_(iib) AlkLE_(vii) 2512 E_(1b)E₂E₃E_(ii)E_(iib) AlkLE_(vii) 2513 E_(1a)E₂E₄ AlkLE_(vii) 2514 E_(1b)E₂E₄ AlkLE_(vii) 2515 E_(1a)E₂E₃E₄ AlkLE_(vii) 2516 E_(1b)E₂E₃E₄ AlkLE_(vii) 2517 E_(1a)E₂E_(i)E₄ AlkLE_(vii) 2518 E_(1b)E₂E_(i)E₄ AlkLE_(vii) 2519 E_(1a)E₂E_(ii)E₄ AlkLE_(vii) 2520 E_(1b)E₂E_(ii)E₄ AlkLE_(vii) 2521 E_(1a)E₂E_(ii)E_(iib)E₄ AlkLE_(vii) 2522 E_(1b)E₂E_(ii)E_(iib)E₄ AlkLE_(vii) 2523 E_(1a)E₂E₃E_(i)E₄ AlkLE_(vii) 2524 E_(1b)E₂E₃E_(i)E₄ AlkLE_(vii) 2525 E_(1a)E₂E₃E_(ii)E₄ AlkLE_(vii) 2526 E_(1b)E₂E₃E_(ii)E₄ AlkLE_(vii) 2527 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(vii) 2528 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(vii) 2529 E_(1a)E₂E_(iii) AlkLE_(vii) 2530 E_(1b)E₂E_(iii) AlkLE_(vii) 2531 E_(1a)E₂E₃E_(iii) AlkLE_(vii) 2532 E_(1b)E₂E₃E_(iii) AlkLE_(vii) 2533 E_(1a)E₂E_(iii)E₄ AlkLE_(vii) 2534 E_(1b)E₂E_(iii)E₄ AlkLE_(vii) 2535 E_(1a)E₂E₃E_(iii)E₄ AlkLE_(vii) 2536 E_(1b)E₂E₃E_(iii)E₄ AlkLE_(vii) 2537 E_(1a)E₂E_(iv) AlkLE_(vii) 2538 E_(1b)E₂E_(iv) AlkLE_(vii) 2539 E_(1a)E₂E₃E_(iv) AlkLE_(vii) 2540 E_(1b)E₂E₃E_(iv) AlkLE_(vii) 2541 E_(1a)E₂E_(iv)E₄ AlkLE_(vii) 2542 E_(1b)E₂E_(iv)E₄ AlkLE_(vii) 2543 E_(1a)E₂E₃E_(iv)E₄ AlkLE_(vii) 2544 E_(1b)E₂E₃E_(iv)E₄ AlkLE_(vii) 2545 E_(1a)E₂ AlkLE_(vii) E₄* 2546 E_(1b)E₂ AlkLE_(vii) E₄* 2547 E_(1a)E₂E₃ AlkLE_(vii) E₄* 2548 E_(1b)E₂E₃ AlkLE_(vii) E₄* 2549 E_(1a)E₂E_(i) AlkLE_(vii) E₄* 2550 E_(1b)E₂E_(i) AlkLE_(vii) E₄* 2551 E_(1a)E₂E_(ii) AlkLE_(vii) E₄* 2552 E_(1b)E₂E_(ii) AlkLE_(vii) E₄* 2553 E_(1a)E₂E_(ii)E_(iib) AlkLE_(vii) E₄* 2554 E_(1b)E₂E_(ii)E_(iib) AlkLE_(vii) E₄* 2555 E_(1a)E₂E₃E_(i) AlkLE_(vii) E₄* 2556 E_(1b)E₂E₃E_(i) AlkLE_(vii) E₄* 2557 E_(1a)E₂E₃E_(ii) AlkLE_(vii) E₄* 2558 E_(1b)E₂E₃E_(ii) AlkLE_(vii) E₄* 2559 E_(1a)E₂E₃E_(ii)E_(iib) AlkLE_(vii) E₄* 2560 E_(1b)E₂E₃E_(ii)E_(iib) AlkLE_(vii) E₄* 2561 E_(1a)E₂E₄ AlkLE_(vii) E₄* 2562 E_(1b)E₂E₄ AlkLE_(vii) E₄* 2563 E_(1a)E₂E₃E₄ AlkLE_(vii) E₄* 2564 E_(1b)E₂E₃E₄ AlkLE_(vii) E₄* 2565 E_(1a)E₂E_(i)E₄ AlkLE_(vii) E₄* 2566 E_(1b)E₂E_(i)E₄ AlkLE_(vii) E₄* 2567 E_(1a)E₂E_(ii)E₄ AlkLE_(vii) E₄* 2568 E_(1b)E₂E_(ii)E₄ AlkLE_(vii) E₄* 2569 E_(1a)E₂E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* 2570 E_(1b)E₂E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* 2571 E_(1a)E₂E₃E_(i)E₄ AlkLE_(vii) E₄* 2572 E_(1b)E₂E₃E_(i)E₄ AlkLE_(vii) E₄* 2573 E_(1a)E₂E₃E_(ii)E₄ AlkLE_(vii) E₄* 2574 E_(1b)E₂E₃E_(ii)E₄ AlkLE_(vii) E₄* 2575 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* 2576 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* 2577 E_(1a)E₂E_(iii) AlkLE_(vii) E₄* 2578 E_(1b)E₂E_(iii) AlkLE_(vii) E₄* 2579 E_(1a)E₂E₃E_(iii) AlkLE_(vii) E₄* 2580 E_(1b)E₂E₃E_(iii) AlkLE_(vii) E₄* 2581 E_(1a)E₂E_(iii)E₄ AlkLE_(vii) E₄* 2582 E_(1b)E₂E_(iii)E₄ AlkLE_(vii) E₄* 2583 E_(1a)E₂E₃E_(iii)E₄ AlkLE_(vii) E₄* 2584 E_(1b)E₂E₃E_(iii)E₄ AlkLE_(vii) E₄* 2585 E_(1a)E₂E_(iv) AlkLE_(vii) E₄* 2586 E_(1b)E₂E_(iv) AlkLE_(vii) E₄* 2587 E_(1a)E₂E₃E_(iv) AlkLE_(vii) E₄* 2588 E_(1b)E₂E₃E_(iv) AlkLE_(vii) E₄* 2589 E_(1a)E₂E_(iv)E₄ AlkLE_(vii) E₄* 2590 E_(1b)E₂E_(iv)E₄ AlkLE_(vii) E₄* 2591 E_(1a)E₂E₃E_(iv)E₄ AlkLE_(vii) E₄* 2592 E_(1b)E₂E₃E_(iv)E₄ AlkLE_(vii) E₄* 2593 E_(1a)E₂ AlkLE_(vii) E₅ 2594 E_(1b)E₂ AlkLE_(vii) E₅ 2595 E_(1a)E₂E₃ AlkLE_(vii) E₅ 2596 E_(1b)E₂E₃ AlkLE_(vii) E₅ 2597 E_(1a)E₂E_(i) AlkLE_(vii) E₅ 2598 E_(1b)E₂E_(i) AlkLE_(vii) E₅ 2599 E_(1a)E₂E_(ii) AlkLE_(vii) E₅ 2600 E_(1b)E₂E_(ii) AlkLE_(vii) E₅ 2601 E_(1a)E₂E_(ii)E_(iib) AlkLE_(vii) E₅ 2602 E_(1b)E₂E_(ii)E_(iib) AlkLE_(vii) E₅ 2603 E_(1a)E₂E₃E_(i) AlkLE_(vii) E₅ 2604 E_(1b)E₂E₃E_(i) AlkLE_(vii) E₅ 2605 E_(1a)E₂E₃E_(ii) AlkLE_(vii) E₅ 2606 E_(1b)E₂E₃E_(ii) AlkLE_(vii) E₅ 2607 E_(1a)E₂E₃E_(ii)E_(iib) AlkLE_(vii) E₅ 2608 E_(1b)E₂E₃E_(ii)E_(iib) AlkLE_(vii) E₅ 2609 E_(1a)E₂E₄ AlkLE_(vii) E₅ 2610 E_(1b)E₂E₄ AlkLE_(vii) E₅ 2611 E_(1a)E₂E₃E₄ AlkLE_(vii) E₅ 2612 E_(1b)E₂E₃E₄ AlkLE_(vii) E₅ 2613 E_(1a)E₂E_(i)E₄ AlkLE_(vii) E₅ 2614 E_(1b)E₂E_(i)E₄ AlkLE_(vii) E₅ 2615 E_(1a)E₂E_(ii)E₄ AlkLE_(vii) E₅ 2616 E_(1b)E₂E_(ii)E₄ AlkLE_(vii) E₅ 2617 E_(1a)E₂E_(ii)E_(iib)E₄ AlkLE_(vii) E₅ 2618 E_(1b)E₂E_(ii)E_(iib)E₄ AlkLE_(vii) E₅ 2619 E_(1a)E₂E₃E_(i)E₄ AlkLE_(vii) E₅ 2620 E_(1b)E₂E₃E_(i)E₄ AlkLE_(vii) E₅ 2621 E_(1a)E₂E₃E_(ii)E₄ AlkLE_(vii) E₅ 2622 E_(1b)E₂E₃E_(ii)E₄ AlkLE_(vii) E₅ 2623 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(vii) E₅ 2624 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(vii) E₅ 2625 E_(1a)E₂E_(iii) AlkLE_(vii) E₅ 2626 E_(1b)E₂E_(iii) AlkLE_(vii) E₅ 2627 E_(1a)E₂E₃E_(iii) AlkLE_(vii) E₅ 2628 E_(1b)E₂E₃E_(iii) AlkLE_(vii) E₅ 2629 E_(1a)E₂E_(iii)E₄ AlkLE_(vii) E₅ 2630 E_(1b)E₂E_(iii)E₄ AlkLE_(vii) E₅ 2631 E_(1a)E₂E₃E_(iii)E₄ AlkLE_(vii) E₅ 2632 E_(1b)E₂E₃E_(iii)E₄ AlkLE_(vii) E₅ 2633 E_(1a)E₂E_(iv) AlkLE_(vii) E₅ 2634 E_(1b)E₂E_(iv) AlkLE_(vii) E₅ 2635 E_(1a)E₂E₃E_(iv) AlkLE_(vii) E₅ 2636 E_(1b)E₂E₃E_(iv) AlkLE_(vii) E₅ 2637 E_(1a)E₂E_(iv)E₄ AlkLE_(vii) E₅ 2638 E_(1b)E₂E_(iv)E₄ AlkLE_(vii) E₅ 2639 E_(1a)E₂E₃E_(iv)E₄ AlkLE_(vii) E₅ 2640 E_(1b)E₂E₃E_(iv)E₄ AlkLE_(vii) E₅ 2641 E_(1a)E₂ AlkLE_(vii) E₄*E₅ 2642 E_(1b)E₂ AlkLE_(vii) E₄*E₅ 2643 E_(1a)E₂E₃ AlkLE_(vii) E₄*E₅ 2644 E_(1b)E₂E₃ AlkLE_(vii) E₄*E₅ 2645 E_(1a)E₂E_(i) AlkLE_(vii) E₄*E₅ 2646 E_(1b)E₂E_(i) AlkLE_(vii) E₄*E₅ 2647 E_(1a)E₂E_(ii) AlkLE_(vii) E₄*E₅ 2648 E_(1b)E₂E_(ii) AlkLE_(vii) E₄*E₅ 2649 E_(1a)E₂E_(ii)E_(iib) AlkLE_(vii) E₄*E₅ 2650 E_(1b)E₂E_(ii)E_(iib) AlkLE_(vii) E₄*E₅ 2651 E_(1a)E₂E₃E_(i) AlkLE_(vii) E₄*E₅ 2652 E_(1b)E₂E₃E_(i) AlkLE_(vii) E₄*E₅ 2653 E_(1a)E₂E₃E_(ii) AlkLE_(vii) E₄*E₅ 2654 E_(1b)E₂E₃E_(ii) AlkLE_(vii) E₄*E₅ 2655 E_(1a)E₂E₃E_(ii)E_(iib) AlkLE_(vii) E₄*E₅ 2656 E_(1b)E₂E₃E_(ii)E_(iib) AlkLE_(vii) E₄*E₅ 2657 E_(1a)E₂E₄ AlkLE_(vii) E₄*E₅ 2658 E_(1b)E₂E₄ AlkLE_(vii) E₄*E₅ 2659 E_(1a)E₂E₃E₄ AlkLE_(vii) E₄*E₅ 2660 E_(1b)E₂E₃E₄ AlkLE_(vii) E₄*E₅ 2661 E_(1a)E₂E_(i)E₄ AlkLE_(vii) E₄*E₅ 2662 E_(1b)E₂E_(i)E₄ AlkLE_(vii) E₄*E₅ 2663 E_(1a)E₂E_(ii)E₄ AlkLE_(vii) E₄*E₅ 2664 E_(1b)E₂E_(ii)E₄ AlkLE_(vii) E₄*E₅ 2665 E_(1a)E₂E_(ii)E_(iib)E₄ AlkLE_(vii) E₄*E₅ 2666 E_(1b)E₂E_(ii)E_(iib)E₄ AlkLE_(vii) E₄*E₅ 2667 E_(1a)E₂E₃E_(i)E₄ AlkLE_(vii) E₄*E₅ 2668 E_(1b)E₂E₃E_(i)E₄ AlkLE_(vii) E₄*E₅ 2669 E_(1a)E₂E₃E_(ii)E₄ AlkLE_(vii) E₄*E₅ 2670 E_(1b)E₂E₃E_(ii)E₄ AlkLE_(vii) E₄*E₅ 2671 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(vii) E₄*E₅ 2672 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(vii) E₄*E₅ 2673 E_(1a)E₂E_(iii) AlkLE_(vii) E₄*E₅ 2674 E_(1b)E₂E_(iii) AlkLE_(vii) E₄*E₅ 2675 E_(1a)E₂E₃E_(iii) AlkLE_(vii) E₄*E₅ 2676 E_(1b)E₂E₃E_(iii) AlkLE_(vii) E₄*E₅ 2677 E_(1a)E₂E_(iii)E₄ AlkLE_(vii) E₄*E₅ 2678 E_(1b)E₂E_(iii)E₄ AlkLE_(vii) E₄*E₅ 2679 E_(1a)E₂E₃E_(iii)E₄ AlkLE_(vii) E₄*E₅ 2680 E_(1b)E₂E₃E_(iii)E₄ AlkLE_(vii) E₄*E₅ 2681 E_(1a)E₂E_(iv) AlkLE_(vii) E₄*E₅ 2682 E_(1b)E₂E_(iv) AlkLE_(vii) E₄*E₅ 2683 E_(1a)E₂E₃E_(iv) AlkLE_(vii) E₄*E₅ 2684 E_(1b)E₂E₃E_(iv) AlkLE_(vii) E₄*E₅ 2685 E_(1a)E₂E_(iv)E₄ AlkLE_(vii) E₄*E₅ 2686 E_(1b)E₂E_(iv)E₄ AlkLE_(vii) E₄*E₅ 2687 E_(1a)E₂E₃E_(iv)E₄ AlkLE_(vii) E₄*E₅ 2688 E_(1b)E₂E₃E_(iv)E₄ AlkLE_(vii) E₄*E₅ 2689 E_(1a)E₂ E_(vii) E_(a) 2690 E_(1b)E₂ E_(vii) E_(a) 2691 E_(1a)E₂E₃ E_(vii) E_(a) 2692 E_(1b)E₂E₃ E_(vii) E_(a) 2693 E_(1a)E₂E_(i) E_(vii) E_(a) 2694 E_(1b)E₂E_(i) E_(vii) E_(a) 2695 E_(1a)E₂E_(ii) E_(vii) E_(a) 2696 E_(1b)E₂E_(ii) E_(vii) E_(a) 2697 E_(1a)E₂E_(ii)E_(iib) E_(vii) E_(a) 2698 E_(1b)E₂E_(ii)E_(iib) E_(vii) E_(a) 2699 E_(1a)E₂E₃E_(i) E_(vii) E_(a) 2700 E_(1b)E₂E₃E_(i) E_(vii) E_(a) 2701 E_(1a)E₂E₃E_(ii) E_(vii) E_(a) 2702 E_(1b)E₂E₃E_(ii) E_(vii) E_(a) 2703 E_(1a)E₂E₃E_(ii)E_(iib) E_(vii) E_(a) 2704 E_(1b)E₂E₃E_(ii)E_(iib) E_(vii) E_(a) 2705 E_(1a)E₂E₄ E_(vii) E_(a) 2706 E_(1b)E₂E₄ E_(vii) E_(a) 2707 E_(1a)E₂E₃E₄ E_(vii) E_(a) 2708 E_(1b)E₂E₃E₄ E_(vii) E_(a) 2709 E_(1a)E₂E_(i)E₄ E_(vii) E_(a) 2710 E_(1b)E₂E_(i)E₄ E_(vii) E_(a) 2711 E_(1a)E₂E_(ii)E₄ E_(vii) E_(a) 2712 E_(1b)E₂E_(ii)E₄ E_(vii) E_(a) 2713 E_(1a)E₂E_(ii)E_(iib)E₄ E_(vii) E_(a) 2714 E_(1b)E₂E_(ii)E_(iib)E₄ E_(vii) E_(a) 2715 E_(1a)E₂E₃E_(i)E₄ E_(vii) E_(a) 2716 E_(1b)E₂E₃E_(i)E₄ E_(vii) E_(a) 2717 E_(1a)E₂E₃E_(ii)E₄ E_(vii) E_(a) 2718 E_(1b)E₂E₃E_(ii)E₄ E_(vii) E_(a) 2719 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E_(vii) E_(a) 2720 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E_(vii) E_(a) 2721 E_(1a)E₂E_(iii) E_(vii) E_(a) 2722 E_(1b)E₂E_(iii) E_(vii) E_(a) 2723 E_(1a)E₂E₃E_(iii) E_(vii) E_(a) 2724 E_(1b)E₂E₃E_(iii) E_(vii) E_(a) 2725 E_(1a)E₂E_(iii)E₄ E_(vii) E_(a) 2726 E_(1b)E₂E_(iii)E₄ E_(vii) E_(a) 2727 E_(1a)E₂E₃E_(iii)E₄ E_(vii) E_(a) 2728 E_(1b)E₂E₃E_(iii)E₄ E_(vii) E_(a) 2729 E_(1a)E₂E_(iv) E_(vii) E_(a) 2730 E_(1b)E₂E_(iv) E_(vii) E_(a) 2731 E_(1a)E₂E₃E_(iv) E_(vii) E_(a) 2732 E_(1b)E₂E₃E_(iv) E_(vii) E_(a) 2733 E_(1a)E₂E_(iv)E₄ E_(vii) E_(a) 2734 E_(1b)E₂E_(iv)E₄ E_(vii) E_(a) 2735 E_(1a)E₂E₃E_(iv)E₄ E_(vii) E_(a) 2736 E_(1b)E₂E₃E_(iv)E₄ E_(vii) E_(a) 2737 E_(1a)E₂ E_(vii) E₄* E_(a) 2738 E_(1b)E₂ E_(vii) E₄* E_(a) 2739 E_(1a)E₂E₃ E_(vii) E₄* E_(a) 2740 E_(1b)E₂E₃ E_(vii) E₄* E_(a) 2741 E_(1a)E₂E_(i) E_(vii) E₄* E_(a) 2742 E_(1b)E₂E_(i) E_(vii) E₄* E_(a) 2743 E_(1a)E₂E_(ii) E_(vii) E₄* E_(a) 2744 E_(1b)E₂E_(ii) E_(vii) E₄* E_(a) 2745 E_(1a)E₂E_(ii)E_(iib) E_(vii) E₄* E_(a) 2746 E_(1b)E₂E_(ii)E_(iib) E_(vii) E₄* E_(a) 2747 E_(1a)E₂E₃E_(i) E_(vii) E₄* E_(a) 2748 E_(1b)E₂E₃E_(i) E_(vii) E₄* E_(a) 2749 E_(1a)E₂E₃E_(ii) E_(vii) E₄* E_(a) 2750 E_(1b)E₂E₃E_(ii) E_(vii) E₄* E_(a) 2751 E_(1a)E₂E₃E_(ii)E_(iib) E_(vii) E₄* E_(a) 2752 E_(1b)E₂E₃E_(ii)E_(iib) E_(vii) E₄* E_(a) 2753 E_(1a)E₂E₄ E_(vii) E₄* E_(a) 2754 E_(1b)E₂E₄ E_(vii) E₄* E_(a) 2755 E_(1a)E₂E₃E₄ E_(vii) E₄* E_(a) 2756 E_(1b)E₂E₃E₄ E_(vii) E₄* E_(a) 2757 E_(1a)E₂E_(i)E₄ E_(vii) E₄* E_(a) 2758 E_(1b)E₂E_(i)E₄ E_(vii) E₄* E_(a) 2759 E_(1a)E₂E_(ii)E₄ E_(vii) E₄* E_(a) 2760 E_(1b)E₂E_(ii)E₄ E_(vii) E₄* E_(a) 2761 E_(1a)E₂E_(ii)E_(iib)E₄ E_(vii) E₄* E_(a) 2762 E_(1b)E₂E_(ii)E_(iib)E₄ E_(vii) E₄* E_(a) 2763 E_(1a)E₂E₃E_(i)E₄ E_(vii) E₄* E_(a) 2764 E_(1b)E₂E₃E_(i)E₄ E_(vii) E₄* E_(a) 2765 E_(1a)E₂E₃E_(ii)E₄ E_(vii) E₄* E_(a) 2766 E_(1b)E₂E₃E_(ii)E₄ E_(vii) E₄* E_(a) 2767 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E_(vii) E₄* E_(a) 2768 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E_(vii) E₄* E_(a) 2769 E_(1a)E₂E_(iii) E_(vii) E₄* E_(a) 2770 E_(1b)E₂E_(iii) E_(vii) E₄* E_(a) 2771 E_(1a)E₂E₃E_(iii) E_(vii) E₄* E_(a) 2772 E_(1b)E₂E₃E_(iii) E_(vii) E₄* E_(a) 2773 E_(1a)E₂E_(iii)E₄ E_(vii) E₄* E_(a) 2774 E_(1b)E₂E_(iii)E₄ E_(vii) E₄* E_(a) 2775 E_(1a)E₂E₃E_(iii)E₄ E_(vii) E₄* E_(a) 2776 E_(1b)E₂E₃E_(iii)E₄ E_(vii) E₄* E_(a) 2777 E_(1a)E₂E_(iv) E_(vii) E₄* E_(a) 2778 E_(1b)E₂E_(iv) E_(vii) E₄* E_(a) 2779 E_(1a)E₂E₃E_(iv) E_(vii) E₄* E_(a) 2780 E_(1b)E₂E₃E_(iv) E_(vii) E₄* E_(a) 2781 E_(1a)E₂E_(iv)E₄ E_(vii) E₄* E_(a) 2782 E_(1b)E₂E_(iv)E₄ E_(vii) E₄* E_(a) 2783 E_(1a)E₂E₃E_(iv)E₄ E_(vii) E₄* E_(a) 2784 E_(1b)E₂E₃E_(iv)E₄ E_(vii) E₄* E_(a) 2785 E_(1a)E₂ E_(vii) E₅ E_(a) 2786 E_(1b)E₂ E_(vii) E₅ E_(a) 2787 E_(1a)E₂E₃ E_(vii) E₅ E_(a) 2788 E_(1b)E₂E₃ E_(vii) E₅ E_(a) 2789 E_(1a)E₂E_(i) E_(vii) E₅ E_(a) 2790 E_(1b)E₂E_(i) E_(vii) E₅ E_(a) 2791 E_(1a)E₂E_(ii) E_(vii) E₅ E_(a) 2792 E_(1b)E₂E_(ii) E_(vii) E₅ E_(a) 2793 E_(1a)E₂E_(ii)E_(iib) E_(vii) E₅ E_(a) 2794 E_(1b)E₂E_(ii)E_(iib) E_(vii) E₅ E_(a) 2795 E_(1a)E₂E₃E_(i) E_(vii) E₅ E_(a) 2796 E_(1b)E₂E₃E_(i) E_(vii) E₅ E_(a) 2797 E_(1a)E₂E₃E_(ii) E_(vii) E₅ E_(a) 2798 E_(1b)E₂E₃E_(ii) E_(vii) E₅ E_(a) 2799 E_(1a)E₂E₃E_(ii)E_(iib) E_(vii) E₅ E_(a) 2800 E_(1b)E₂E₃E_(ii)E_(iib) E_(vii) E₅ E_(a) 2801 E_(1a)E₂E₄ E_(vii) E₅ E_(a) 2802 E_(1b)E₂E₄ E_(vii) E₅ E_(a) 2803 E_(1a)E₂E₃E₄ E_(vii) E₅ E_(a) 2804 E_(1b)E₂E₃E₄ E_(vii) E₅ E_(a) 2805 E_(1a)E₂E_(i)E₄ E_(vii) E₅ E_(a) 2806 E_(1b)E₂E_(i)E₄ E_(vii) E₅ E_(a) 2807 E_(1a)E₂E_(ii)E₄ E_(vii) E₅ E_(a) 2808 E_(1b)E₂E_(ii)E₄ E_(vii) E₅ E_(a) 2809 E_(1a)E₂E_(ii)E_(iib)E₄ E_(vii) E₅ E_(a) 2810 E_(1b)E₂E_(ii)E_(iib)E₄ E_(vii) E₅ E_(a) 2811 E_(1a)E₂E₃E_(i)E₄ E_(vii) E₅ E_(a) 2812 E_(1b)E₂E₃E_(i)E₄ E_(vii) E₅ E_(a) 2813 E_(1a)E₂E₃E_(ii)E₄ E_(vii) E₅ E_(a) 2814 E_(1b)E₂E₃E_(ii)E₄ E_(vii) E₅ E_(a) 2815 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E_(vii) E₅ E_(a) 2816 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E_(vii) E₅ E_(a) 2817 E_(1a)E₂E_(iii) E_(vii) E₅ E_(a) 2818 E_(1b)E₂E_(iii) E_(vii) E₅ E_(a) 2819 E_(1a)E₂E₃E_(iii) E_(vii) E₅ E_(a) 2820 E_(1b)E₂E₃E_(iii) E_(vii) E₅ E_(a) 2821 E_(1a)E₂E_(iii)E₄ E_(vii) E₅ E_(a) 2822 E_(1b)E₂E_(iii)E₄ E_(vii) E₅ E_(a) 2823 E_(1a)E₂E₃E_(iii)E₄ E_(vii) E₅ E_(a) 2824 E_(1b)E₂E₃E_(iii)E₄ E_(vii) E₅ E_(a) 2825 E_(1a)E₂E_(iv) E_(vii) E₅ E_(a) 2826 E_(1b)E₂E_(iv) E_(vii) E₅ E_(a) 2827 E_(1a)E₂E₃E_(iv) E_(vii) E₅ E_(a) 2828 E_(1b)E₂E₃E_(iv) E_(vii) E₅ E_(a) 2829 E_(1a)E₂E_(iv)E₄ E_(vii) E₅ E_(a) 2830 E_(1b)E₂E_(iv)E₄ E_(vii) E₅ E_(a) 2831 E_(1a)E₂E₃E_(iv)E₄ E_(vii) E₅ E_(a) 2832 E_(1b)E₂E₃E_(iv)E₄ E_(vii) E₅ E_(a) 2833 E_(1a)E₂ E_(vii) E₄*E₅ E_(a) 2834 E_(1b)E₂ E_(vii) E₄*E₅ E_(a) 2835 E_(1a)E₂E₃ E_(vii) E₄*E₅ E_(a) 2836 E_(1b)E₂E₃ E_(vii) E₄*E₅ E_(a) 2837 E_(1a)E₂E_(i) E_(vii) E₄*E₅ E_(a) 2838 E_(1b)E₂E_(i) E_(vii) E₄*E₅ E_(a) 2839 E_(1a)E₂E_(ii) E_(vii) E₄*E₅ E_(a) 2840 E_(1b)E₂E_(ii) E_(vii) E₄*E₅ E_(a) 2841 E_(1a)E₂E_(ii)E_(iib) E_(vii) E₄*E₅ E_(a) 2842 E_(1b)E₂E_(ii)E_(iib) E_(vii) E₄*E₅ E_(a) 2843 E_(1a)E₂E₃E_(i) E_(vii) E₄*E₅ E_(a) 2844 E_(1b)E₂E₃E_(i) E_(vii) E₄*E₅ E_(a) 2845 E_(1a)E₂E₃E_(ii) E_(vii) E₄*E₅ E_(a) 2846 E_(1b)E₂E₃E_(ii) E_(vii) E₄*E₅ E_(a) 2847 E_(1a)E₂E₃E_(ii)E_(iib) E_(vii) E₄*E₅ E_(a) 2848 E_(1b)E₂E₃E_(ii)E_(iib) E_(vii) E₄*E₅ E_(a) 2849 E_(1a)E₂E₄ E_(vii) E₄*E₅ E_(a) 2850 E_(1b)E₂E₄ E_(vii) E₄*E₅ E_(a) 2851 E_(1a)E₂E₃E₄ E_(vii) E₄*E₅ E_(a) 2852 E_(1b)E₂E₃E₄ E_(vii) E₄*E₅ E_(a) 2853 E_(1a)E₂E_(i)E₄ E_(vii) E₄*E₅ E_(a) 2854 E_(1b)E₂E_(i)E₄ E_(vii) E₄*E₅ E_(a) 2855 E_(1a)E₂E_(ii)E₄ E_(vii) E₄*E₅ E_(a) 2856 E_(1b)E₂E_(ii)E₄ E_(vii) E₄*E₅ E_(a) 2857 E_(1a)E₂E_(ii)E_(iib)E₄ E_(vii) E₄*E₅ E_(a) 2858 E_(1b)E₂E_(ii)E_(iib)E₄ E_(vii) E₄*E₅ E_(a) 2859 E_(1a)E₂E₃E_(i)E₄ E_(vii) E₄*E₅ E_(a) 2860 E_(1b)E₂E₃E_(i)E₄ E_(vii) E₄*E₅ E_(a) 2861 E_(1a)E₂E₃E_(ii)E₄ E_(vii) E₄*E₅ E_(a) 2862 E_(1b)E₂E₃E_(ii)E₄ E_(vii) E₄*E₅ E_(a) 2863 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E_(vii) E₄*E₅ E_(a) 2864 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E_(vii) E₄*E₅ E_(a) 2865 E_(1a)E₂E_(iii) E_(vii) E₄*E₅ E_(a) 2866 E_(1b)E₂E_(iii) E_(vii) E₄*E₅ E_(a) 2867 E_(1a)E₂E₃E_(iii) E_(vii) E₄*E₅ E_(a) 2868 E_(1b)E₂E₃E_(iii) E_(vii) E₄*E₅ E_(a) 2869 E_(1a)E₂E_(iii)E₄ E_(vii) E₄*E₅ E_(a) 2870 E_(1b)E₂E_(iii)E₄ E_(vii) E₄*E₅ E_(a) 2871 E_(1a)E₂E₃E_(iii)E₄ E_(vii) E₄*E₅ E_(a) 2872 E_(1b)E₂E₃E_(iii)E₄ E_(vii) E₄*E₅ E_(a) 2873 E_(1a)E₂E_(iv) E_(vii) E₄*E₅ E_(a) 2874 E_(1b)E₂E_(iv) E_(vii) E₄*E₅ E_(a) 2875 E_(1a)E₂E₃E_(iv) E_(vii) E₄*E₅ E_(a) 2876 E_(1b)E₂E₃E_(iv) E_(vii) E₄*E₅ E_(a) 2877 E_(1a)E₂E_(iv)E₄ E_(vii) E₄*E₅ E_(a) 2878 E_(1b)E₂E_(iv)E₄ E_(vii) E₄*E₅ E_(a) 2879 E_(1a)E₂E₃E_(iv)E₄ E_(vii) E₄*E₅ E_(a) 2880 E_(1b)E₂E₃E_(iv)E₄ E_(vii) E₄*E₅ E_(a) 2881 E_(1a)E₂ AlkLE_(vii) E_(a) 2882 E_(1b)E₂ AlkLE_(vii) E_(a) 2883 E_(1a)E₂E₃ AlkLE_(vii) E_(a) 2884 E_(1b)E₂E₃ AlkLE_(vii) E_(a) 2885 E_(1a)E₂E_(i) AlkLE_(vii) E_(a) 2886 E_(1b)E₂E_(i) AlkLE_(vii) E_(a) 2887 E_(1a)E₂E_(ii) AlkLE_(vii) E_(a) 2888 E_(1b)E₂E_(ii) AlkLE_(vii) E_(a) 2889 E_(1a)E₂E_(ii)E_(iib) AlkLE_(vii) E_(a) 2890 E_(1b)E₂E_(ii)E_(iib) AlkLE_(vii) E_(a) 2891 E_(1a)E₂E₃E_(i) AlkLE_(vii) E_(a) 2892 E_(1b)E₂E₃E_(i) AlkLE_(vii) E_(a) 2893 E_(1a)E₂E₃E_(ii) AlkLE_(vii) E_(a) 2894 E_(1b)E₂E₃E_(ii) AlkLE_(vii) E_(a) 2895 E_(1a)E₂E₃E_(ii)E_(iib) AlkLE_(vii) E_(a) 2896 E_(1b)E₂E₃E_(ii)E_(iib) AlkLE_(vii) E_(a) 2897 E_(1a)E₂E₄ AlkLE_(vii) E_(a) 2898 E_(1b)E₂E₄ AlkLE_(vii) E_(a) 2899 E_(1a)E₂E₃E₄ AlkLE_(vii) E_(a) 2900 E_(1b)E₂E₃E₄ AlkLE_(vii) E_(a) 2901 E_(1a)E₂E_(i)E₄ AlkLE_(vii) E_(a) 2902 E_(1b)E₂E_(i)E₄ AlkLE_(vii) E_(a) 2903 E_(1a)E₂E_(ii)E₄ AlkLE_(vii) E_(a) 2904 E_(1b)E₂E_(ii)E₄ AlkLE_(vii) E_(a) 2905 E_(1a)E₂E_(ii)E_(iib)E₄ AlkLE_(vii) E_(a) 2906 E_(1b)E₂E_(ii)E_(iib)E₄ AlkLE_(vii) E_(a) 2907 E_(1a)E₂E₃E_(i)E₄ AlkLE_(vii) E_(a) 2908 E_(1b)E₂E₃E_(i)E₄ AlkLE_(vii) E_(a) 2909 E_(1a)E₂E₃E_(ii)E₄ AlkLE_(vii) E_(a) 2910 E_(1b)E₂E₃E_(ii)E₄ AlkLE_(vii) E_(a) 2911 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(vii) E_(a) 2912 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(vii) E_(a) 2913 E_(1a)E₂E_(iii) AlkLE_(vii) E_(a) 2914 E_(1b)E₂E_(iii) AlkLE_(vii) E_(a) 2915 E_(1a)E₂E₃E_(iii) AlkLE_(vii) E_(a) 2916 E_(1b)E₂E₃E_(iii) AlkLE_(vii) E_(a) 2917 E_(1a)E₂E_(iii)E₄ AlkLE_(vii) E_(a) 2918 E_(1b)E₂E_(iii)E₄ AlkLE_(vii) E_(a) 2919 E_(1a)E₂E₃E_(iii)E₄ AlkLE_(vii) E_(a) 2920 E_(1b)E₂E₃E_(iii)E₄ AlkLE_(vii) E_(a) 2921 E_(1a)E₂E_(iv) AlkLE_(vii) E_(a) 2922 E_(1b)E₂E_(iv) AlkLE_(vii) E_(a) 2923 E_(1a)E₂E₃E_(iv) AlkLE_(vii) E_(a) 2924 E_(1b)E₂E₃E_(iv) AlkLE_(vii) E_(a) 2925 E_(1a)E₂E_(iv)E₄ AlkLE_(vii) E_(a) 2926 E_(1b)E₂E_(iv)E₄ AlkLE_(vii) E_(a) 2927 E_(1a)E₂E₃E_(iv)E₄ AlkLE_(vii) E_(a) 2928 E_(1b)E₂E₃E_(iv)E₄ AlkLE_(vii) E_(a) 2929 E_(1a)E₂ AlkLE_(vii) E₄* E_(a) 2930 E_(1b)E₂ AlkLE_(vii) E₄* E_(a) 2931 E_(1a)E₂E₃ AlkLE_(vii) E₄* E_(a) 2932 E_(1b)E₂E₃ AlkLE_(vii) E₄* E_(a) 2933 E_(1a)E₂E_(i) AlkLE_(vii) E₄* E_(a) 2934 E_(1b)E₂E_(i) AlkLE_(vii) E₄* E_(a) 2935 E_(1a)E₂E_(ii) AlkLE_(vii) E₄* E_(a) 2936 E_(1b)E₂E_(ii) AlkLE_(vii) E₄* E_(a) 2937 E_(1a)E₂E_(ii)E_(iib) AlkLE_(vii) E₄* E_(a) 2938 E_(1b)E₂E_(ii)E_(iib) AlkLE_(vii) E₄* E_(a) 2939 E_(1a)E₂E₃E_(i) AlkLE_(vii) E₄* E_(a) 2940 E_(1b)E₂E₃E_(i) AlkLE_(vii) E₄* E_(a) 2941 E_(1a)E₂E₃E_(ii) AlkLE_(vii) E₄* E_(a) 2942 E_(1b)E₂E₃E_(ii) AlkLE_(vii) E₄* E_(a) 2943 E_(1a)E₂E₃E_(ii)E_(iib) AlkLE_(vii) E₄* E_(a) 2944 E_(1b)E₂E₃E_(ii)E_(iib) AlkLE_(vii) E₄* E_(a) 2945 E_(1a)E₂E₄ AlkLE_(vii) E₄* E_(a) 2946 E_(1b)E₂E₄ AlkLE_(vii) E₄* E_(a) 2947 E_(1a)E₂E₃E₄ AlkLE_(vii) E₄* E_(a) 2948 E_(1b)E₂E₃E₄ AlkLE_(vii) E₄* E_(a) 2949 E_(1a)E₂E_(i)E₄ AlkLE_(vii) E₄* E_(a) 2950 E_(1b)E₂E_(i)E₄ AlkLE_(vii) E₄* E_(a) 2951 E_(1a)E₂E_(ii)E₄ AlkLE_(vii) E₄* E_(a) 2952 E_(1b)E₂E_(ii)E₄ AlkLE_(vii) E₄* E_(a) 2953 E_(1a)E₂E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* E_(a) 2954 E_(1b)E₂E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* E_(a) 2955 E_(1a)E₂E₃E_(i)E₄ AlkLE_(vii) E₄* E_(a) 2956 E_(1b)E₂E₃E_(i)E₄ AlkLE_(vii) E₄* E_(a) 2957 E_(1a)E₂E₃E_(ii)E₄ AlkLE_(vii) E₄* E_(a) 2958 E_(1b)E₂E₃E_(ii)E₄ AlkLE_(vii) E₄* E_(a) 2959 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* E_(a) 2960 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* E_(a) 2961 E_(1a)E₂E_(iii) AlkLE_(vii) E₄* E_(a) 2962 E_(1b)E₂E_(iii) AlkLE_(vii) E₄* E_(a) 2963 E_(1a)E₂E₃E_(iii) AlkLE_(vii) E₄* E_(a) 2964 E_(1b)E₂E₃E_(iii) AlkLE_(vii) E₄* E_(a) 2965 E_(1a)E₂E_(iii)E₄ AlkLE_(vii) E₄* E_(a) 2966 E_(1b)E₂E_(iii)E₄ AlkLE_(vii) E₄* E_(a) 2967 E_(1a)E₂E₃E_(iii)E₄ AlkLE_(vii) E₄* E_(a) 2968 E_(1b)E₂E₃E_(iii)E₄ AlkLE_(vii) E₄* E_(a) 2969 E_(1a)E₂E_(iv) AlkLE_(vii) E₄* E_(a) 2970 E_(1b)E₂E_(iv) AlkLE_(vii) E₄* E_(a) 2971 E_(1a)E₂E₃E_(iv) AlkLE_(vii) E₄* E_(a) 2972 E_(1b)E₂E₃E_(iv) AlkLE_(vii) E₄* E_(a) 2973 E_(1a)E₂E_(iv)E₄ AlkLE_(vii) E₄* E_(a) 2974 E_(1b)E₂E_(iv)E₄ AlkLE_(vii) E₄* E_(a) 2975 E_(1a)E₂E₃E_(iv)E₄ AlkLE_(vii) E₄* E_(a) 2976 E_(1b)E₂E₃E_(iv)E₄ AlkLE_(vii) E₄* E_(a) 2977 E_(1a)E₂ AlkLE_(vii) E₅ E_(a) 2978 E_(1b)E₂ AlkLE_(vii) E₅ E_(a) 2979 E_(1a)E₂E₃ AlkLE_(vii) E₅ E_(a) 2980 E_(1b)E₂E₃ AlkLE_(vii) E₅ E_(a) 2981 E_(1a)E₂E_(i) AlkLE_(vii) E₅ E_(a) 2982 E_(1b)E₂E_(i) AlkLE_(vii) E₅ E_(a) 2983 E_(1a)E₂E_(ii) AlkLE_(vii) E₅ E_(a) 2984 E_(1b)E₂E_(ii) AlkLE_(vii) E₅ E_(a) 2985 E_(1a)E₂E_(ii)E_(iib) AlkLE_(vii) E₅ E_(a) 2986 E_(1b)E₂E_(ii)E_(iib) AlkLE_(vii) E₅ E_(a) 2987 E_(1a)E₂E₃E_(i) AlkLE_(vii) E₅ E_(a) 2988 E_(1b)E₂E₃E_(i) AlkLE_(vii) E₅ E_(a) 2989 E_(1a)E₂E₃E_(ii) AlkLE_(vii) E₅ E_(a) 2990 E_(1b)E₂E₃E_(ii) AlkLE_(vii) E₅ E_(a) 2991 E_(1a)E₂E₃E_(ii)E_(iib) AlkLE_(vii) E₅ E_(a) 2992 E_(1b)E₂E₃E_(ii)E_(iib) AlkLE_(vii) E₅ E_(a) 2993 E_(1a)E₂E₄ AlkLE_(vii) E₅ E_(a) 2994 E_(1b)E₂E₄ AlkLE_(vii) E₅ E_(a) 2995 E_(1a)E₂E₃E₄ AlkLE_(vii) E₅ E_(a) 2996 E_(1b)E₂E₃E₄ AlkLE_(vii) E₅ E_(a) 2997 E_(1a)E₂E_(i)E₄ AlkLE_(vii) E₅ E_(a) 2998 E_(1b)E₂E_(i)E₄ AlkLE_(vii) E₅ E_(a) 2999 E_(1a)E₂E_(ii)E₄ AlkLE_(vii) E₅ E_(a) 3000 E_(1b)E₂E_(ii)E₄ AlkLE_(vii) E₅ E_(a) 3001 E_(1a)E₂E_(ii)E_(iib)E₄ AlkLE_(vii) E₅ E_(a) 3002 E_(1b)E₂E_(ii)E_(iib)E₄ AlkLE_(vii) E₅ E_(a) 3003 E_(1a)E₂E₃E_(i)E₄ AlkLE_(vii) E₅ E_(a) 3004 E_(1b)E₂E₃E_(i)E₄ AlkLE_(vii) E₅ E_(a) 3005 E_(1a)E₂E₃E_(ii)E₄ AlkLE_(vii) E₅ E_(a) 3006 E_(1b)E₂E₃E_(ii)E₄ AlkLE_(vii) E₅ E_(a) 3007 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(vii) E₅ E_(a) 3008 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(vii) E₅ E_(a) 3009 E_(1a)E₂E_(iii) AlkLE_(vii) E₅ E_(a) 3010 E_(1b)E₂E_(iii) AlkLE_(vii) E₅ E_(a) 3011 E_(1a)E₂E₃E_(iii) AlkLE_(vii) E₅ E_(a) 3012 E_(1b)E₂E₃E_(iii) AlkLE_(vii) E₅ E_(a) 3013 E_(1a)E₂E_(iii)E₄ AlkLE_(vii) E₅ E_(a) 3014 E_(1b)E₂E_(iii)E₄ AlkLE_(vii) E₅ E_(a) 3015 E_(1a)E₂E₃E_(iii)E₄ AlkLE_(vii) E₅ E_(a) 3016 E_(1b)E₂E₃E_(iii)E₄ AlkLE_(vii) E₅ E_(a) 3017 E_(1a)E₂E_(iv) AlkLE_(vii) E₅ E_(a) 3018 E_(1b)E₂E_(iv) AlkLE_(vii) E₅ E_(a) 3019 E_(1a)E₂E₃E_(iv) AlkLE_(vii) E₅ E_(a) 3020 E_(1b)E₂E₃E_(iv) AlkLE_(vii) E₅ E_(a) 3021 E_(1a)E₂E_(iv)E₄ AlkLE_(vii) E₅ E_(a) 3022 E_(1b)E₂E_(iv)E₄ AlkLE_(vii) E₅ E_(a) 3023 E_(1a)E₂E₃E_(iv)E₄ AlkLE_(vii) E₅ E_(a) 3024 E_(1b)E₂E₃E_(iv)E₄ AlkLE_(vii) E₅ E_(a) 3025 E_(1a)E₂ AlkLE_(vii) E₄*E₅ E_(a) 3026 E_(1b)E₂ AlkLE_(vii) E₄*E₅ E_(a) 3027 E_(1a)E₂E₃ AlkLE_(vii) E₄*E₅ E_(a) 3028 E_(1b)E₂E₃ AlkLE_(vii) E₄*E₅ E_(a) 3029 E_(1a)E₂E_(i) AlkLE_(vii) E₄*E₅ E_(a) 3030 E_(1b)E₂E_(i) AlkLE_(vii) E₄*E₅ E_(a) 3031 E_(1a)E₂E_(ii) AlkLE_(vii) E₄*E₅ E_(a) 3032 E_(1b)E₂E_(ii) AlkLE_(vii) E₄*E₅ E_(a) 3033 E_(1a)E₂E_(ii)E_(iib) AlkLE_(vii) E₄*E₅ E_(a) 3034 E_(1b)E₂E_(ii)E_(iib) AlkLE_(vii) E₄*E₅ E_(a) 3035 E_(1a)E₂E₃E_(i) AlkLE_(vii) E₄*E₅ E_(a) 3036 E_(1b)E₂E₃E_(i) AlkLE_(vii) E₄*E₅ E_(a) 3037 E_(1a)E₂E₃E_(ii) AlkLE_(vii) E₄*E₅ E_(a) 3038 E_(1b)E₂E₃E_(ii) AlkLE_(vii) E₄*E₅ E_(a) 3039 E_(1a)E₂E₃E_(ii)E_(iib) AlkLE_(vii) E₄*E₅ E_(a) 3040 E_(1b)E₂E₃E_(ii)E_(iib) AlkLE_(vii) E₄*E₅ E_(a) 3041 E_(1a)E₂E₄ AlkLE_(vii) E₄*E₅ E_(a) 3042 E_(1b)E₂E₄ AlkLE_(vii) E₄*E₅ E_(a) 3043 E_(1a)E₂E₃E₄ AlkLE_(vii) E₄*E₅ E_(a) 3044 E_(1b)E₂E₃E₄ AlkLE_(vii) E₄*E₅ E_(a) 3045 E_(1a)E₂E_(i)E₄ AlkLE_(vii) E₄*E₅ E_(a) 3046 E_(1b)E₂E_(i)E₄ AlkLE_(vii) E₄*E₅ E_(a) 3047 E_(1a)E₂E_(ii)E₄ AlkLE_(vii) E₄*E₅ E_(a) 3048 E_(1b)E₂E_(ii)E₄ AlkLE_(vii) E₄*E₅ E_(a) 3049 E_(1a)E₂E_(ii)E_(iib)E₄ AlkLE_(vii) E₄*E₅ E_(a) 3050 E_(1b)E₂E_(ii)E_(iib)E₄ AlkLE_(vii) E₄*E₅ E_(a) 3051 E_(1a)E₂E₃E_(i)E₄ AlkLE_(vii) E₄*E₅ E_(a) 3052 E_(1b)E₂E₃E_(i)E₄ AlkLE_(vii) E₄*E₅ E_(a) 3053 E_(1a)E₂E₃E_(ii)E₄ AlkLE_(vii) E₄*E₅ E_(a) 3054 E_(1b)E₂E₃E_(ii)E₄ AlkLE_(vii) E₄*E₅ E_(a) 3055 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(vii) E₄*E₅ E_(a) 3056 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(vii) E₄*E₅ E_(a) 3057 E_(1a)E₂E_(iii) AlkLE_(vii) E₄*E₅ E_(a) 3058 E_(1b)E₂E_(iii) AlkLE_(vii) E₄*E₅ E_(a) 3059 E_(1a)E₂E₃E_(iii) AlkLE_(vii) E₄*E₅ E_(a) 3060 E_(1b)E₂E₃E_(iii) AlkLE_(vii) E₄*E₅ E_(a) 3061 E_(1a)E₂E_(iii)E₄ AlkLE_(vii) E₄*E₅ E_(a) 3062 E_(1b)E₂E_(iii)E₄ AlkLE_(vii) E₄*E₅ E_(a) 3063 E_(1a)E₂E₃E_(iii)E₄ AlkLE_(vii) E₄*E₅ E_(a) 3064 E_(1b)E₂E₃E_(iii)E₄ AlkLE_(vii) E₄*E₅ E_(a) 3065 E_(1a)E₂E_(iv) AlkLE_(vii) E₄*E₅ E_(a) 3066 E_(1b)E₂E_(iv) AlkLE_(vii) E₄*E₅ E_(a) 3067 E_(1a)E₂E₃E_(iv) AlkLE_(vii) E₄*E₅ E_(a) 3068 E_(1b)E₂E₃E_(iv) AlkLE_(vii) E₄*E₅ E_(a) 3069 E_(1a)E₂E_(iv)E₄ AlkLE_(vii) E₄*E₅ E_(a) 3070 E_(1b)E₂E_(iv)E₄ AlkLE_(vii) E₄*E₅ E_(a) 3071 E_(1a)E₂E₃E_(iv)E₄ AlkLE_(vii) E₄*E₅ E_(a) 3072 E_(1b)E₂E₃E_(iv)E₄ AlkLE_(vii) E₄*E₅ E_(a) 3073 E_(1a)E₂ E_(vii) E_(b) 3074 E_(1b)E₂ E_(vii) E_(b) 3075 E_(1a)E₂E₃ E_(vii) E_(b) 3076 E_(1b)E₂E₃ E_(vii) E_(b) 3077 E_(1a)E₂E_(i) E_(vii) E_(b) 3078 E_(1b)E₂E_(i) E_(vii) E_(b) 3079 E_(1a)E₂E_(ii) E_(vii) E_(b) 3080 E_(1b)E₂E_(ii) E_(vii) E_(b) 3081 E_(1a)E₂E_(ii)E_(iib) E_(vii) E_(b) 3082 E_(1b)E₂E_(ii)E_(iib) E_(vii) E_(b) 3083 E_(1a)E₂E₃E_(i) E_(vii) E_(b) 3084 E_(1b)E₂E₃E_(i) E_(vii) E_(b) 3085 E_(1a)E₂E₃E_(ii) E_(vii) E_(b) 3086 E_(1b)E₂E₃E_(ii) E_(vii) E_(b) 3087 E_(1a)E₂E₃E_(ii)E_(iib) E_(vii) E_(b) 3088 E_(1b)E₂E₃E_(ii)E_(iib) E_(vii) E_(b) 3089 E_(1a)E₂E₄ E_(vii) E_(b) 3090 E_(1b)E₂E₄ E_(vii) E_(b) 3091 E_(1a)E₂E₃E₄ E_(vii) E_(b) 3092 E_(1b)E₂E₃E₄ E_(vii) E_(b) 3093 E_(1a)E₂E_(i)E₄ E_(vii) E_(b) 3094 E_(1b)E₂E_(i)E₄ E_(vii) E_(b) 3095 E_(1a)E₂E_(ii)E₄ E_(vii) E_(b) 3096 E_(1b)E₂E_(ii)E₄ E_(vii) E_(b) 3097 E_(1a)E₂E_(ii)E_(iib)E₄ E_(vii) E_(b) 3098 E_(1b)E₂E_(ii)E_(iib)E₄ E_(vii) E_(b) 3099 E_(1a)E₂E₃E_(i)E₄ E_(vii) E_(b) 3100 E_(1b)E₂E₃E_(i)E₄ E_(vii) E_(b) 3101 E_(1a)E₂E₃E_(ii)E₄ E_(vii) E_(b) 3102 E_(1b)E₂E₃E_(ii)E₄ E_(vii) E_(b) 3103 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E_(vii) E_(b) 3104 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E_(vii) E_(b) 3105 E_(1a)E₂E_(iii) E_(vii) E_(b) 3106 E_(1b)E₂E_(iii) E_(vii) E_(b) 3107 E_(1a)E₂E₃E_(iii) E_(vii) E_(b) 3108 E_(1b)E₂E₃E_(iii) E_(vii) E_(b) 3109 E_(1a)E₂E_(iii)E₄ E_(vii) E_(b) 3110 E_(1b)E₂E_(iii)E₄ E_(vii) E_(b) 3111 E_(1a)E₂E₃E_(iii)E₄ E_(vii) E_(b) 3112 E_(1b)E₂E₃E_(iii)E₄ E_(vii) E_(b) 3113 E_(1a)E₂E_(iv) E_(vii) E_(b) 3114 E_(1b)E₂E_(iv) E_(vii) E_(b) 3115 E_(1a)E₂E₃E_(iv) E_(vii) E_(b) 3116 E_(1b)E₂E₃E_(iv) E_(vii) E_(b) 3117 E_(1a)E₂E_(iv)E₄ E_(vii) E_(b) 3118 E_(1b)E₂E_(iv)E₄ E_(vii) E_(b) 3119 E_(1a)E₂E₃E_(iv)E₄ E_(vii) E_(b) 3120 E_(1b)E₂E₃E_(iv)E₄ E_(vii) E_(b) 3121 E_(1a)E₂ E_(vii) E₄* E_(b) 3122 E_(1b)E₂ E_(vii) E₄* E_(b) 3123 E_(1a)E₂E₃ E_(vii) E₄* E_(b) 3124 E_(1b)E₂E₃ E_(vii) E₄* E_(b) 3125 E_(1a)E₂E_(i) E_(vii) E₄* E_(b) 3126 E_(1b)E₂E_(i) E_(vii) E₄* E_(b) 3127 E_(1a)E₂E_(ii) E_(vii) E₄* E_(b) 3128 E_(1b)E₂E_(ii) E_(vii) E₄* E_(b) 3129 E_(1a)E₂E_(ii)E_(iib) E_(vii) E₄* E_(b) 3130 E_(1b)E₂E_(ii)E_(iib) E_(vii) E₄* E_(b) 3131 E_(1a)E₂E₃E_(i) E_(vii) E₄* E_(b) 3132 E_(1b)E₂E₃E_(i) E_(vii) E₄* E_(b) 3133 E_(1a)E₂E₃E_(ii) E_(vii) E₄* E_(b) 3134 E_(1b)E₂E₃E_(ii) E_(vii) E₄* E_(b) 3135 E_(1a)E₂E₃E_(ii)E_(iib) E_(vii) E₄* E_(b) 3136 E_(1b)E₂E₃E_(ii)E_(iib) E_(vii) E₄* E_(b) 3137 E_(1a)E₂E₄ E_(vii) E₄* E_(b) 3138 E_(1b)E₂E₄ E_(vii) E₄* E_(b) 3139 E_(1a)E₂E₃E₄ E_(vii) E₄* E_(b) 3140 E_(1b)E₂E₃E₄ E_(vii) E₄* E_(b) 3141 E_(1a)E₂E_(i)E₄ E_(vii) E₄* E_(b) 3142 E_(1b)E₂E_(i)E₄ E_(vii) E₄* E_(b) 3143 E_(1a)E₂E_(ii)E₄ E_(vii) E₄* E_(b) 3144 E_(1b)E₂E_(ii)E₄ E_(vii) E₄* E_(b) 3145 E_(1a)E₂E_(ii)E_(iib)E₄ E_(vii) E₄* E_(b) 3146 E_(1b)E₂E_(ii)E_(iib)E₄ E_(vii) E₄* E_(b) 3147 E_(1a)E₂E₃E_(i)E₄ E_(vii) E₄* E_(b) 3148 E_(1b)E₂E₃E_(i)E₄ E_(vii) E₄* E_(b) 3149 E_(1a)E₂E₃E_(ii)E₄ E_(vii) E₄* E_(b) 3150 E_(1b)E₂E₃E_(ii)E₄ E_(vii) E₄* E_(b) 3151 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E_(vii) E₄* E_(b) 3152 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E_(vii) E₄* E_(b) 3153 E_(1a)E₂E_(iii) E_(vii) E₄* E_(b) 3154 E_(1b)E₂E_(iii) E_(vii) E₄* E_(b) 3155 E_(1a)E₂E₃E_(iii) E_(vii) E₄* E_(b) 3156 E_(1b)E₂E₃E_(iii) E_(vii) E₄* E_(b) 3157 E_(1a)E₂E_(iii)E₄ E_(vii) E₄* E_(b) 3158 E_(1b)E₂E_(iii)E₄ E_(vii) E₄* E_(b) 3159 E_(1a)E₂E₃E_(iii)E₄ E_(vii) E₄* E_(b) 3160 E_(1b)E₂E₃E_(iii)E₄ E_(vii) E₄* E_(b) 3161 E_(1a)E₂E_(iv) E_(vii) E₄* E_(b) 3162 E_(1b)E₂E_(iv) E_(vii) E₄* E_(b) 3163 E_(1a)E₂E₃E_(iv) E_(vii) E₄* E_(b) 3164 E_(1b)E₂E₃E_(iv) E_(vii) E₄* E_(b) 3165 E_(1a)E₂E_(iv)E₄ E_(vii) E₄* E_(b) 3166 E_(1b)E₂E_(iv)E₄ E_(vii) E₄* E_(b) 3167 E_(1a)E₂E₃E_(iv)E₄ E_(vii) E₄* E_(b) 3168 E_(1b)E₂E₃E_(iv)E₄ E_(vii) E₄* E_(b) 3169 E_(1a)E₂ E_(vii) E₅ E_(b) 3170 E_(1b)E₂ E_(vii) E₅ E_(b) 3171 E_(1a)E₂E₃ E_(vii) E₅ E_(b) 3172 E_(1b)E₂E₃ E_(vii) E₅ E_(b) 3173 E_(1a)E₂E_(i) E_(vii) E₅ E_(b) 3174 E_(1b)E₂E_(i) E_(vii) E₅ E_(b) 3175 E_(1a)E₂E_(ii) E_(vii) E₅ E_(b) 3176 E_(1b)E₂E_(ii) E_(vii) E₅ E_(b) 3177 E_(1a)E₂E_(ii)E_(iib) E_(vii) E₅ E_(b) 3178 E_(1b)E₂E_(ii)E_(iib) E_(vii) E₅ E_(b) 3179 E_(1a)E₂E₃E_(i) E_(vii) E₅ E_(b) 3180 E_(1b)E₂E₃E_(i) E_(vii) E₅ E_(b) 3181 E_(1a)E₂E₃E_(ii) E_(vii) E₅ E_(b) 3182 E_(1b)E₂E₃E_(ii) E_(vii) E₅ E_(b) 3183 E_(1a)E₂E₃E_(ii)E_(iib) E_(vii) E₅ E_(b) 3184 E_(1b)E₂E₃E_(ii)E_(iib) E_(vii) E₅ E_(b) 3185 E_(1a)E₂E₄ E_(vii) E₅ E_(b) 3186 E_(1b)E₂E₄ E_(vii) E₅ E_(b) 3187 E_(1a)E₂E₃E₄ E_(vii) E₅ E_(b) 3188 E_(1b)E₂E₃E₄ E_(vii) E₅ E_(b) 3189 E_(1a)E₂E_(i)E₄ E_(vii) E₅ E_(b) 3190 E_(1b)E₂E_(i)E₄ E_(vii) E₅ E_(b) 3191 E_(1a)E₂E_(ii)E₄ E_(vii) E₅ E_(b) 3192 E_(1b)E₂E_(ii)E₄ E_(vii) E₅ E_(b) 3193 E_(1a)E₂E_(ii)E_(iib)E₄ E_(vii) E₅ E_(b) 3194 E_(1b)E₂E_(ii)E_(iib)E₄ E_(vii) E₅ E_(b) 3195 E_(1a)E₂E₃E_(i)E₄ E_(vii) E₅ E_(b) 3196 E_(1b)E₂E₃E_(i)E₄ E_(vii) E₅ E_(b) 3197 E_(1a)E₂E₃E_(ii)E₄ E_(vii) E₅ E_(b) 3198 E_(1b)E₂E₃E_(ii)E₄ E_(vii) E₅ E_(b) 3199 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E_(vii) E₅ E_(b) 3200 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E_(vii) E₅ E_(b) 3201 E_(1a)E₂E_(iii) E_(vii) E₅ E_(b) 3202 E_(1b)E₂E_(iii) E_(vii) E₅ E_(b) 3203 E_(1a)E₂E₃E_(iii) E_(vii) E₅ E_(b) 3204 E_(1b)E₂E₃E_(iii) E_(vii) E₅ E_(b) 3205 E_(1a)E₂E_(iii)E₄ E_(vii) E₅ E_(b) 3206 E_(1b)E₂E_(iii)E₄ E_(vii) E₅ E_(b) 3207 E_(1a)E₂E₃E_(iii)E₄ E_(vii) E₅ E_(b) 3208 E_(1b)E₂E₃E_(iii)E₄ E_(vii) E₅ E_(b) 3209 E_(1a)E₂E_(iv) E_(vii) E₅ E_(b) 3210 E_(1b)E₂E_(iv) E_(vii) E₅ E_(b) 3211 E_(1a)E₂E₃E_(iv) E_(vii) E₅ E_(b) 3212 E_(1b)E₂E₃E_(iv) E_(vii) E₅ E_(b) 3213 E_(1a)E₂E_(iv)E₄ E_(vii) E₅ E_(b) 3214 E_(1b)E₂E_(iv)E₄ E_(vii) E₅ E_(b) 3215 E_(1a)E₂E₃E_(iv)E₄ E_(vii) E₅ E_(b) 3216 E_(1b)E₂E₃E_(iv)E₄ E_(vii) E₅ E_(b) 3217 E_(1a)E₂ E_(vii) E₄*E₅ E_(b) 3218 E_(1b)E₂ E_(vii) E₄*E₅ E_(b) 3219 E_(1a)E₂E₃ E_(vii) E₄*E₅ E_(b) 3220 E_(1b)E₂E₃ E_(vii) E₄*E₅ E_(b) 3221 E_(1a)E₂E_(i) E_(vii) E₄*E₅ E_(b) 3222 E_(1b)E₂E_(i) E_(vii) E₄*E₅ E_(b) 3223 E_(1a)E₂E_(ii) E_(vii) E₄*E₅ E_(b) 3224 E_(1b)E₂E_(ii) E_(vii) E₄*E₅ E_(b) 3225 E_(1a)E₂E_(ii)E_(iib) E_(vii) E₄*E₅ E_(b) 3226 E_(1b)E₂E_(ii)E_(iib) E_(vii) E₄*E₅ E_(b) 3227 E_(1a)E₂E₃E_(i) E_(vii) E₄*E₅ E_(b) 3228 E_(1b)E₂E₃E_(i) E_(vii) E₄*E₅ E_(b) 3229 E_(1a)E₂E₃E_(ii) E_(vii) E₄*E₅ E_(b) 3230 E_(1b)E₂E₃E_(ii) E_(vii) E₄*E₅ E_(b) 3231 E_(1a)E₂E₃E_(ii)E_(iib) E_(vii) E₄*E₅ E_(b) 3232 E_(1b)E₂E₃E_(ii)E_(iib) E_(vii) E₄*E₅ E_(b) 3233 E_(1a)E₂E₄ E_(vii) E₄*E₅ E_(b) 3234 E_(1b)E₂E₄ E_(vii) E₄*E₅ E_(b) 3235 E_(1a)E₂E₃E₄ E_(vii) E₄*E₅ E_(b) 3236 E_(1b)E₂E₃E₄ E_(vii) E₄*E₅ E_(b) 3237 E_(1a)E₂E_(i)E₄ E_(vii) E₄*E₅ E_(b) 3238 E_(1b)E₂E_(i)E₄ E_(vii) E₄*E₅ E_(b) 3239 E_(1a)E₂E_(ii)E₄ E_(vii) E₄*E₅ E_(b) 3240 E_(1b)E₂E_(ii)E₄ E_(vii) E₄*E₅ E_(b) 3241 E_(1a)E₂E_(ii)E_(iib)E₄ E_(vii) E₄*E₅ E_(b) 3242 E_(1b)E₂E_(ii)E_(iib)E₄ E_(vii) E₄*E₅ E_(b) 3243 E_(1a)E₂E₃E_(i)E₄ E_(vii) E₄*E₅ E_(b) 3244 E_(1b)E₂E₃E_(i)E₄ E_(vii) E₄*E₅ E_(b) 3245 E_(1a)E₂E₃E_(ii)E₄ E_(vii) E₄*E₅ E_(b) 3246 E_(1b)E₂E₃E_(ii)E₄ E_(vii) E₄*E₅ E_(b) 3247 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E_(vii) E₄*E₅ E_(b) 3248 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E_(vii) E₄*E₅ E_(b) 3249 E_(1a)E₂E_(iii) E_(vii) E₄*E₅ E_(b) 3250 E_(1b)E₂E_(iii) E_(vii) E₄*E₅ E_(b) 3251 E_(1a)E₂E₃E_(iii) E_(vii) E₄*E₅ E_(b) 3252 E_(1b)E₂E₃E_(iii) E_(vii) E₄*E₅ E_(b) 3253 E_(1a)E₂E_(iii)E₄ E_(vii) E₄*E₅ E_(b) 3254 E_(1b)E₂E_(iii)E₄ E_(vii) E₄*E₅ E_(b) 3255 E_(1a)E₂E₃E_(iii)E₄ E_(vii) E₄*E₅ E_(b) 3256 E_(1b)E₂E₃E_(iii)E₄ E_(vii) E₄*E₅ E_(b) 3257 E_(1a)E₂E_(iv) E_(vii) E₄*E₅ E_(b) 3258 E_(1b)E₂E_(iv) E_(vii) E₄*E₅ E_(b) 3259 E_(1a)E₂E₃E_(iv) E_(vii) E₄*E₅ E_(b) 3260 E_(1b)E₂E₃E_(iv) E_(vii) E₄*E₅ E_(b) 3261 E_(1a)E₂E_(iv)E₄ E_(vii) E₄*E₅ E_(b) 3262 E_(1b)E₂E_(iv)E₄ E_(vii) E₄*E₅ E_(b) 3263 E_(1a)E₂E₃E_(iv)E₄ E_(vii) E₄*E₅ E_(b) 3264 E_(1b)E₂E₃E_(iv)E₄ E_(vii) E₄*E₅ E_(b) 3265 E_(1a)E₂ AlkLE_(vii) E_(b) 3266 E_(1b)E₂ AlkLE_(vii) E_(b) 3267 E_(1a)E₂E₃ AlkLE_(vii) E_(b) 3268 E_(1b)E₂E₃ AlkLE_(vii) E_(b) 3269 E_(1a)E₂E_(i) AlkLE_(vii) E_(b) 3270 E_(1b)E₂E_(i) AlkLE_(vii) E_(b) 3271 E_(1a)E₂E_(ii) AlkLE_(vii) E_(b) 3272 E_(1b)E₂E_(ii) AlkLE_(vii) E_(b) 3273 E_(1a)E₂E_(ii)E_(iib) AlkLE_(vii) E_(b) 3274 E_(1b)E₂E_(ii)E_(iib) AlkLE_(vii) E_(b) 3275 E_(1a)E₂E₃E_(i) AlkLE_(vii) E_(b) 3276 E_(1b)E₂E₃E_(i) AlkLE_(vii) E_(b) 3277 E_(1a)E₂E₃E_(ii) AlkLE_(vii) E_(b) 3278 E_(1b)E₂E₃E_(ii) AlkLE_(vii) E_(b) 3279 E_(1a)E₂E₃E_(ii)E_(iib) AlkLE_(vii) E_(b) 3280 E_(1b)E₂E₃E_(ii)E_(iib) AlkLE_(vii) E_(b) 3281 E_(1a)E₂E₄ AlkLE_(vii) E_(b) 3282 E_(1b)E₂E₄ AlkLE_(vii) E_(b) 3283 E_(1a)E₂E₃E₄ AlkLE_(vii) E_(b) 3284 E_(1b)E₂E₃E₄ AlkLE_(vii) E_(b) 3285 E_(1a)E₂E_(i)E₄ AlkLE_(vii) E_(b) 3286 E_(1b)E₂E_(i)E₄ AlkLE_(vii) E_(b) 3287 E_(1a)E₂E_(ii)E₄ AlkLE_(vii) E_(b) 3288 E_(1b)E₂E_(ii)E₄ AlkLE_(vii) E_(b) 3289 E_(1a)E₂E_(ii)E_(iib)E₄ AlkLE_(vii) E_(b) 3290 E_(1b)E₂E_(ii)E_(iib)E₄ AlkLE_(vii) E_(b) 3291 E_(1a)E₂E₃E_(i)E₄ AlkLE_(vii) E_(b) 3292 E_(1b)E₂E₃E_(i)E₄ AlkLE_(vii) E_(b) 3293 E_(1a)E₂E₃E_(ii)E₄ AlkLE_(vii) E_(b) 3294 E_(1b)E₂E₃E_(ii)E₄ AlkLE_(vii) E_(b) 3295 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(vii) E_(b) 3296 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(vii) E_(b) 3297 E_(1a)E₂E_(iii) AlkLE_(vii) E_(b) 3298 E_(1b)E₂E_(iii) AlkLE_(vii) E_(b) 3299 E_(1a)E₂E₃E_(iii) AlkLE_(vii) E_(b) 3300 E_(1b)E₂E₃E_(iii) AlkLE_(vii) E_(b) 3301 E_(1a)E₂E_(iii)E₄ AlkLE_(vii) E_(b) 3302 E_(1b)E₂E_(iii)E₄ AlkLE_(vii) E_(b) 3303 E_(1a)E₂E₃E_(iii)E₄ AlkLE_(vii) E_(b) 3304 E_(1b)E₂E₃E_(iii)E₄ AlkLE_(vii) E_(b) 3305 E_(1a)E₂E_(iv) AlkLE_(vii) E_(b) 3306 E_(1b)E₂E_(iv) AlkLE_(vii) E_(b) 3307 E_(1a)E₂E₃E_(iv) AlkLE_(vii) E_(b) 3308 E_(1b)E₂E₃E_(iv) AlkLE_(vii) E_(b) 3309 E_(1a)E₂E_(iv)E₄ AlkLE_(vii) E_(b) 3310 E_(1b)E₂E_(iv)E₄ AlkLE_(vii) E_(b) 3311 E_(1a)E₂E₃E_(iv)E₄ AlkLE_(vii) E_(b) 3312 E_(1b)E₂E₃E_(iv)E₄ AlkLE_(vii) E_(b) 3313 E_(1a)E₂ AlkLE_(vii) E₄* E_(b) 3314 E_(1b)E₂ AlkLE_(vii) E₄* E_(b) 3315 E_(1a)E₂E₃ AlkLE_(vii) E₄* E_(b) 3316 E_(1b)E₂E₃ AlkLE_(vii) E₄* E_(b) 3317 E_(1a)E₂E_(i) AlkLE_(vii) E₄* E_(b) 3318 E_(1b)E₂E_(i) AlkLE_(vii) E₄* E_(b) 3319 E_(1a)E₂E_(ii) AlkLE_(vii) E₄* E_(b) 3320 E_(1b)E₂E_(ii) AlkLE_(vii) E₄* E_(b) 3321 E_(1a)E₂E_(ii)E_(iib) AlkLE_(vii) E₄* E_(b) 3322 E_(1b)E₂E_(ii)E_(iib) AlkLE_(vii) E₄* E_(b) 3323 E_(1a)E₂E₃E_(i) AlkLE_(vii) E₄* E_(b) 3324 E_(1b)E₂E₃E_(i) AlkLE_(vii) E₄* E_(b) 3325 E_(1a)E₂E₃E_(ii) AlkLE_(vii) E₄* E_(b) 3326 E_(1b)E₂E₃E_(ii) AlkLE_(vii) E₄* E_(b) 3327 E_(1a)E₂E₃E_(ii)E_(iib) AlkLE_(vii) E₄* E_(b) 3328 E_(1b)E₂E₃E_(ii)E_(iib) AlkLE_(vii) E₄* E_(b) 3329 E_(1a)E₂E₄ AlkLE_(vii) E₄* E_(b) 3330 E_(1b)E₂E₄ AlkLE_(vii) E₄* E_(b) 3331 E_(1a)E₂E₃E₄ AlkLE_(vii) E₄* E_(b) 3332 E_(1b)E₂E₃E₄ AlkLE_(vii) E₄* E_(b) 3333 E_(1a)E₂E_(i)E₄ AlkLE_(vii) E₄* E_(b) 3334 E_(1b)E₂E_(i)E₄ AlkLE_(vii) E₄* E_(b) 3335 E_(1a)E₂E_(ii)E₄ AlkLE_(vii) E₄* E_(b) 3336 E_(1b)E₂E_(ii)E₄ AlkLE_(vii) E₄* E_(b) 3337 E_(1a)E₂E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* E_(b) 3338 E_(1b)E₂E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* E_(b) 3339 E_(1a)E₂E₃E_(i)E₄ AlkLE_(vii) E₄* E_(b) 3340 E_(1b)E₂E₃E_(i)E₄ AlkLE_(vii) E₄* E_(b) 3341 E_(1a)E₂E₃E_(ii)E₄ AlkLE_(vii) E₄* E_(b) 3342 E_(1b)E₂E₃E_(ii)E₄ AlkLE_(vii) E₄* E_(b) 3343 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* E_(b) 3344 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* E_(b) 3345 E_(1a)E₂E_(iii) AlkLE_(vii) E₄* E_(b) 3346 E_(1b)E₂E_(iii) AlkLE_(vii) E₄* E_(b) 3347 E_(1a)E₂E₃E_(iii) AlkLE_(vii) E₄* E_(b) 3348 E_(1b)E₂E₃E_(iii) AlkLE_(vii) E₄* E_(b) 3349 E_(1a)E₂E_(iii)E₄ AlkLE_(vii) E₄* E_(b) 3350 E_(1b)E₂E_(iii)E₄ AlkLE_(vii) E₄* E_(b) 3351 E_(1a)E₂E₃E_(iii)E₄ AlkLE_(vii) E₄* E_(b) 3352 E_(1b)E₂E₃E_(iii)E₄ AlkLE_(vii) E₄* E_(b) 3353 E_(1a)E₂E_(iv) AlkLE_(vii) E₄* E_(b) 3354 E_(1b)E₂E_(iv) AlkLE_(vii) E₄* E_(b) 3355 E_(1a)E₂E₃E_(iv) AlkLE_(vii) E₄* E_(b) 3356 E_(1b)E₂E₃E_(iv) AlkLE_(vii) E₄* E_(b) 3357 E_(1a)E₂E_(iv)E₄ AlkLE_(vii) E₄* E_(b) 3358 E_(1b)E₂E_(iv)E₄ AlkLE_(vii) E₄* E_(b) 3359 E_(1a)E₂E₃E_(iv)E₄ AlkLE_(vii) E₄* E_(b) 3360 E_(1b)E₂E₃E_(iv)E₄ AlkLE_(vii) E₄* E_(b) 3361 E_(1a)E₂ AlkLE_(vii) E₅ E_(b) 3362 E_(1b)E₂ AlkLE_(vii) E₅ E_(b) 3363 E_(1a)E₂E₃ AlkLE_(vii) E₅ E_(b) 3364 E_(1b)E₂E₃ AlkLE_(vii) E₅ E_(b) 3365 E_(1a)E₂E_(i) AlkLE_(vii) E₅ E_(b) 3366 E_(1b)E₂E_(i) AlkLE_(vii) E₅ E_(b) 3367 E_(1a)E₂E_(ii) AlkLE_(vii) E₅ E_(b) 3368 E_(1b)E₂E_(ii) AlkLE_(vii) E₅ E_(b) 3369 E_(1a)E₂E_(ii)E_(iib) AlkLE_(vii) E₅ E_(b) 3370 E_(1b)E₂E_(ii)E_(iib) AlkLE_(vii) E₅ E_(b) 3371 E_(1a)E₂E₃E_(i) AlkLE_(vii) E₅ E_(b) 3372 E_(1b)E₂E₃E_(i) AlkLE_(vii) E₅ E_(b) 3373 E_(1a)E₂E₃E_(ii) AlkLE_(vii) E₅ E_(b) 3374 E_(1b)E₂E₃E_(ii) AlkLE_(vii) E₅ E_(b) 3375 E_(1a)E₂E₃E_(ii)E_(iib) AlkLE_(vii) E₅ E_(b) 3376 E_(1b)E₂E₃E_(ii)E_(iib) AlkLE_(vii) E₅ E_(b) 3377 E_(1a)E₂E₄ AlkLE_(vii) E₅ E_(b) 3378 E_(1b)E₂E₄ AlkLE_(vii) E₅ E_(b) 3379 E_(1a)E₂E₃E₄ AlkLE_(vii) E₅ E_(b) 3380 E_(1b)E₂E₃E₄ AlkLE_(vii) E₅ E_(b) 3381 E_(1a)E₂E_(i)E₄ AlkLE_(vii) E₅ E_(b) 3382 E_(1b)E₂E_(i)E₄ AlkLE_(vii) E₅ E_(b) 3383 E_(1a)E₂E_(ii)E₄ AlkLE_(vii) E₅ E_(b) 3384 E_(1b)E₂E_(ii)E₄ AlkLE_(vii) E₅ E_(b) 3385 E_(1a)E₂E_(ii)E_(iib)E₄ AlkLE_(vii) E₅ E_(b) 3386 E_(1b)E₂E_(ii)E_(iib)E₄ AlkLE_(vii) E₅ E_(b) 3387 E_(1a)E₂E₃E_(i)E₄ AlkLE_(vii) E₅ E_(b) 3388 E_(1b)E₂E₃E_(i)E₄ AlkLE_(vii) E₅ E_(b) 3389 E_(1a)E₂E₃E_(ii)E₄ AlkLE_(vii) E₅ E_(b) 3390 E_(1b)E₂E₃E_(ii)E₄ AlkLE_(vii) E₅ E_(b) 3391 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(vii) E₅ E_(b) 3392 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(vii) E₅ E_(b) 3393 E_(1a)E₂E_(iii) AlkLE_(vii) E₅ E_(b) 3394 E_(1b)E₂E_(iii) AlkLE_(vii) E₅ E_(b) 3395 E_(1a)E₂E₃E_(iii) AlkLE_(vii) E₅ E_(b) 3396 E_(1b)E₂E₃E_(iii) AlkLE_(vii) E₅ E_(b) 3397 E_(1a)E₂E_(iii)E₄ AlkLE_(vii) E₅ E_(b) 3398 E_(1b)E₂E_(iii)E₄ AlkLE_(vii) E₅ E_(b) 3399 E_(1a)E₂E₃E_(iii)E₄ AlkLE_(vii) E₅ E_(b) 3400 E_(1b)E₂E₃E_(iii)E₄ AlkLE_(vii) E₅ E_(b) 3401 E_(1a)E₂E_(iv) AlkLE_(vii) E₅ E_(b) 3402 E_(1b)E₂E_(iv) AlkLE_(vii) E₅ E_(b) 3403 E_(1a)E₂E₃E_(iv) AlkLE_(vii) E₅ E_(b) 3404 E_(1b)E₂E₃E_(iv) AlkLE_(vii) E₅ E_(b) 3405 E_(1a)E₂E_(iv)E₄ AlkLE_(vii) E₅ E_(b) 3406 E_(1b)E₂E_(iv)E₄ AlkLE_(vii) E₅ E_(b) 3407 E_(1a)E₂E₃E_(iv)E₄ AlkLE_(vii) E₅ E_(b) 3408 E_(1b)E₂E₃E_(iv)E₄ AlkLE_(vii) E₅ E_(b) 3409 E_(1a)E₂ AlkLE_(vii) E₄*E₅ E_(b) 3410 E_(1b)E₂ AlkLE_(vii) E₄*E₅ E_(b) 3411 E_(1a)E₂E₃ AlkLE_(vii) E₄*E₅ E_(b) 3412 E_(1b)E₂E₃ AlkLE_(vii) E₄*E₅ E_(b) 3413 E_(1a)E₂E_(i) AlkLE_(vii) E₄*E₅ E_(b) 3414 E_(1b)E₂E_(i) AlkLE_(vii) E₄*E₅ E_(b) 3415 E_(1a)E₂E_(ii) AlkLE_(vii) E₄*E₅ E_(b) 3416 E_(1b)E₂E_(ii) AlkLE_(vii) E₄*E₅ E_(b) 3417 E_(1a)E₂E_(ii)E_(iib) AlkLE_(vii) E₄*E₅ E_(b) 3418 E_(1b)E₂E_(ii)E_(iib) AlkLE_(vii) E₄*E₅ E_(b) 3419 E_(1a)E₂E₃E_(i) AlkLE_(vii) E₄*E₅ E_(b) 3420 E_(1b)E₂E₃E_(i) AlkLE_(vii) E₄*E₅ E_(b) 3421 E_(1a)E₂E₃E_(ii) AlkLE_(vii) E₄*E₅ E_(b) 3422 E_(1b)E₂E₃E_(ii) AlkLE_(vii) E₄*E₅ E_(b) 3423 E_(1a)E₂E₃E_(ii)E_(iib) AlkLE_(vii) E₄*E₅ E_(b) 3424 E_(1b)E₂E₃E_(ii)E_(iib) AlkLE_(vii) E₄*E₅ E_(b) 3425 E_(1a)E₂E₄ AlkLE_(vii) E₄*E₅ E_(b) 3426 E_(1b)E₂E₄ AlkLE_(vii) E₄*E₅ E_(b) 3427 E_(1a)E₂E₃E₄ AlkLE_(vii) E₄*E₅ E_(b) 3428 E_(1b)E₂E₃E₄ AlkLE_(vii) E₄*E₅ E_(b) 3429 E_(1a)E₂E_(i)E₄ AlkLE_(vii) E₄*E₅ E_(b) 3430 E_(1b)E₂E_(i)E₄ AlkLE_(vii) E₄*E₅ E_(b) 3431 E_(1a)E₂E_(ii)E₄ AlkLE_(vii) E₄*E₅ E_(b) 3432 E_(1b)E₂E_(ii)E₄ AlkLE_(vii) E₄*E₅ E_(b) 3433 E_(1a)E₂E_(ii)E_(iib)E₄ AlkLE_(vii) E₄*E₅ E_(b) 3434 E_(1b)E₂E_(ii)E_(iib)E₄ AlkLE_(vii) E₄*E₅ E_(b) 3435 E_(1a)E₂E₃E_(i)E₄ AlkLE_(vii) E₄*E₅ E_(b) 3436 E_(1b)E₂E₃E_(i)E₄ AlkLE_(vii) E₄*E₅ E_(b) 3437 E_(1a)E₂E₃E_(ii)E₄ AlkLE_(vii) E₄*E₅ E_(b) 3438 E_(1b)E₂E₃E_(ii)E₄ AlkLE_(vii) E₄*E₅ E_(b) 3439 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(vii) E₄*E₅ E_(b) 3440 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(vii) E₄*E₅ E_(b) 3441 E_(1a)E₂E_(iii) AlkLE_(vii) E₄*E₅ E_(b) 3442 E_(1b)E₂E_(iii) AlkLE_(vii) E₄*E₅ E_(b) 3443 E_(1a)E₂E₃E_(iii) AlkLE_(vii) E₄*E₅ E_(b) 3444 E_(1b)E₂E₃E_(iii) AlkLE_(vii) E₄*E₅ E_(b) 3445 E_(1a)E₂E_(iii)E₄ AlkLE_(vii) E₄*E₅ E_(b) 3446 E_(1b)E₂E_(iii)E₄ AlkLE_(vii) E₄*E₅ E_(b) 3447 E_(1a)E₂E₃E_(iii)E₄ AlkLE_(vii) E₄*E₅ E_(b) 3448 E_(1b)E₂E₃E_(iii)E₄ AlkLE_(vii) E₄*E₅ E_(b) 3449 E_(1a)E₂E_(iv) AlkLE_(vii) E₄*E₅ E_(b) 3450 E_(1b)E₂E_(iv) AlkLE_(vii) E₄*E₅ E_(b) 3451 E_(1a)E₂E₃E_(iv) AlkLE_(vii) E₄*E₅ E_(b) 3452 E_(1b)E₂E₃E_(iv) AlkLE_(vii) E₄*E₅ E_(b) 3453 E_(1a)E₂E_(iv)E₄ AlkLE_(vii) E₄*E₅ E_(b) 3454 E_(1b)E₂E_(iv)E₄ AlkLE_(vii) E₄*E₅ E_(b) 3455 E_(1a)E₂E₃E_(iv)E₄ AlkLE_(vii) E₄*E₅ E_(b) 3456 E_(1b)E₂E₃E_(iv)E₄ AlkLE_(vii) E₄*E₅ E_(b) 3457 E_(1a)E₂ E_(vii) E_(d) 3458 E_(1b)E₂ E_(vii) E_(d) 3459 E_(1a)E₂E₃ E_(vii) E_(d) 3460 E_(1b)E₂E₃ E_(vii) E_(d) 3461 E_(1a)E₂E_(i) E_(vii) E_(d) 3462 E_(1b)E₂E_(i) E_(vii) E_(d) 3463 E_(1a)E₂E_(ii) E_(vii) E_(d) 3464 E_(1b)E₂E_(ii) E_(vii) E_(d) 3465 E_(1a)E₂E_(ii)E_(iib) E_(vii) E_(d) 3466 E_(1b)E₂E_(ii)E_(iib) E_(vii) E_(d) 3467 E_(1a)E₂E₃E_(i) E_(vii) E_(d) 3468 E_(1b)E₂E₃E_(i) E_(vii) E_(d) 3469 E_(1a)E₂E₃E_(ii) E_(vii) E_(d) 3470 E_(1b)E₂E₃E_(ii) E_(vii) E_(d) 3471 E_(1a)E₂E₃E_(ii)E_(iib) E_(vii) E_(d) 3472 E_(1b)E₂E₃E_(ii)E_(iib) E_(vii) E_(d) 3473 E_(1a)E₂E₄ E_(vii) E_(d) 3474 E_(1b)E₂E₄ E_(vii) E_(d) 3475 E_(1a)E₂E₃E₄ E_(vii) E_(d) 3476 E_(1b)E₂E₃E₄ E_(vii) E_(d) 3477 E_(1a)E₂E_(i)E₄ E_(vii) E_(d) 3478 E_(1b)E₂E_(i)E₄ E_(vii) E_(d) 3479 E_(1a)E₂E_(ii)E₄ E_(vii) E_(d) 3480 E_(1b)E₂E_(ii)E₄ E_(vii) E_(d) 3481 E_(1a)E₂E_(ii)E_(iib)E₄ E_(vii) E_(d) 3482 E_(1b)E₂E_(ii)E_(iib)E₄ E_(vii) E_(d) 3483 E_(1a)E₂E₃E_(i)E₄ E_(vii) E_(d) 3484 E_(1b)E₂E₃E_(i)E₄ E_(vii) E_(d) 3485 E_(1a)E₂E₃E_(ii)E₄ E_(vii) E_(d) 3486 E_(1b)E₂E₃E_(ii)E₄ E_(vii) E_(d) 3487 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E_(vii) E_(d) 3488 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E_(vii) E_(d) 3489 E_(1a)E₂E_(iii) E_(vii) E_(d) 3490 E_(1b)E₂E_(iii) E_(vii) E_(d) 3491 E_(1a)E₂E₃E_(iii) E_(vii) E_(d) 3492 E_(1b)E₂E₃E_(iii) E_(vii) E_(d) 3493 E_(1a)E₂E_(iii)E₄ E_(vii) E_(d) 3494 E_(1b)E₂E_(iii)E₄ E_(vii) E_(d) 3495 E_(1a)E₂E₃E_(iii)E₄ E_(vii) E_(d) 3496 E_(1b)E₂E₃E_(iii)E₄ E_(vii) E_(d) 3497 E_(1a)E₂E_(iv) E_(vii) E_(d) 3498 E_(1b)E₂E_(iv) E_(vii) E_(d) 3499 E_(1a)E₂E₃E_(iv) E_(vii) E_(d) 3500 E_(1b)E₂E₃E_(iv) E_(vii) E_(d) 3501 E_(1a)E₂E_(iv)E₄ E_(vii) E_(d) 3502 E_(1b)E₂E_(iv)E₄ E_(vii) E_(d) 3503 E_(1a)E₂E₃E_(iv)E₄ E_(vii) E_(d) 3504 E_(1b)E₂E₃E_(iv)E₄ E_(vii) E_(d) 3505 E_(1a)E₂ E_(vii) E₄* E_(d) 3506 E_(1b)E₂ E_(vii) E₄* E_(d) 3507 E_(1a)E₂E₃ E_(vii) E₄* E_(d) 3508 E_(1b)E₂E₃ E_(vii) E₄* E_(d) 3509 E_(1a)E₂E_(i) E_(vii) E₄* E_(d) 3510 E_(1b)E₂E_(i) E_(vii) E₄* E_(d) 3511 E_(1a)E₂E_(ii) E_(vii) E₄* E_(d) 3512 E_(1b)E₂E_(ii) E_(vii) E₄* E_(d) 3513 E_(1a)E₂E_(ii)E_(iib) E_(vii) E₄* E_(d) 3514 E_(1b)E₂E_(ii)E_(iib) E_(vii) E₄* E_(d) 3515 E_(1a)E₂E₃E_(i) E_(vii) E₄* E_(d) 3516 E_(1b)E₂E₃E_(i) E_(vii) E₄* E_(d) 3517 E_(1a)E₂E₃E_(ii) E_(vii) E₄* E_(d) 3518 E_(1b)E₂E₃E_(ii) E_(vii) E₄* E_(d) 3519 E_(1a)E₂E₃E_(ii)E_(iib) E_(vii) E₄* E_(d) 3520 E_(1b)E₂E₃E_(ii)E_(iib) E_(vii) E₄* E_(d) 3521 E_(1a)E₂E₄ E_(vii) E₄* E_(d) 3522 E_(1b)E₂E₄ E_(vii) E₄* E_(d) 3523 E_(1a)E₂E₃E₄ E_(vii) E₄* E_(d) 3524 E_(1b)E₂E₃E₄ E_(vii) E₄* E_(d) 3525 E_(1a)E₂E_(i)E₄ E_(vii) E₄* E_(d) 3526 E_(1b)E₂E_(i)E₄ E_(vii) E₄* E_(d) 3527 E_(1a)E₂E_(ii)E₄ E_(vii) E₄* E_(d) 3528 E_(1b)E₂E_(ii)E₄ E_(vii) E₄* E_(d) 3529 E_(1a)E₂E_(ii)E_(iib)E₄ E_(vii) E₄* E_(d) 3530 E_(1b)E₂E_(ii)E_(iib)E₄ E_(vii) E₄* E_(d) 3531 E_(1a)E₂E₃E_(i)E₄ E_(vii) E₄* E_(d) 3532 E_(1b)E₂E₃E_(i)E₄ E_(vii) E₄* E_(d) 3533 E_(1a)E₂E₃E_(ii)E₄ E_(vii) E₄* E_(d) 3534 E_(1b)E₂E₃E_(ii)E₄ E_(vii) E₄* E_(d) 3535 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E_(vii) E₄* E_(d) 3536 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E_(vii) E₄* E_(d) 3537 E_(1a)E₂E_(iii) E_(vii) E₄* E_(d) 3538 E_(1b)E₂E_(iii) E_(vii) E₄* E_(d) 3539 E_(1a)E₂E₃E_(iii) E_(vii) E₄* E_(d) 3540 E_(1b)E₂E₃E_(iii) E_(vii) E₄* E_(d) 3541 E_(1a)E₂E_(iii)E₄ E_(vii) E₄* E_(d) 3542 E_(1b)E₂E_(iii)E₄ E_(vii) E₄* E_(d) 3543 E_(1a)E₂E₃E_(iii)E₄ E_(vii) E₄* E_(d) 3544 E_(1b)E₂E₃E_(iii)E₄ E_(vii) E₄* E_(d) 3545 E_(1a)E₂E_(iv) E_(vii) E₄* E_(d) 3546 E_(1b)E₂E_(iv) E_(vii) E₄* E_(d) 3547 E_(1a)E₂E₃E_(iv) E_(vii) E₄* E_(d) 3548 E_(1b)E₂E₃E_(iv) E_(vii) E₄* E_(d) 3549 E_(1a)E₂E_(iv)E₄ E_(vii) E₄* E_(d) 3550 E_(1b)E₂E_(iv)E₄ E_(vii) E₄* E_(d) 3551 E_(1a)E₂E₃E_(iv)E₄ E_(vii) E₄* E_(d) 3552 E_(1b)E₂E₃E_(iv)E₄ E_(vii) E₄* E_(d) 3553 E_(1a)E₂ E_(vii) E₅ E_(d) 3554 E_(1b)E₂ E_(vii) E₅ E_(d) 3555 E_(1a)E₂E₃ E_(vii) E₅ E_(d) 3556 E_(1b)E₂E₃ E_(vii) E₅ E_(d) 3557 E_(1a)E₂E_(i) E_(vii) E₅ E_(d) 3558 E_(1b)E₂E_(i) E_(vii) E₅ E_(d) 3559 E_(1a)E₂E_(ii) E_(vii) E₅ E_(d) 3560 E_(1b)E₂E_(ii) E_(vii) E₅ E_(d) 3561 E_(1a)E₂E_(ii)E_(iib) E_(vii) E₅ E_(d) 3562 E_(1b)E₂E_(ii)E_(iib) E_(vii) E₅ E_(d) 3563 E_(1a)E₂E₃E_(i) E_(vii) E₅ E_(d) 3564 E_(1b)E₂E₃E_(i) E_(vii) E₅ E_(d) 3565 E_(1a)E₂E₃E_(ii) E_(vii) E₅ E_(d) 3566 E_(1b)E₂E₃E_(ii) E_(vii) E₅ E_(d) 3567 E_(1a)E₂E₃E_(ii)E_(iib) E_(vii) E₅ E_(d) 3568 E_(1b)E₂E₃E_(ii)E_(iib) E_(vii) E₅ E_(d) 3569 E_(1a)E₂E₄ E_(vii) E₅ E_(d) 3570 E_(1b)E₂E₄ E_(vii) E₅ E_(d) 3571 E_(1a)E₂E₃E₄ E_(vii) E₅ E_(d) 3572 E_(1b)E₂E₃E₄ E_(vii) E₅ E_(d) 3573 E_(1a)E₂E_(i)E₄ E_(vii) E₅ E_(d) 3574 E_(1b)E₂E_(i)E₄ E_(vii) E₅ E_(d) 3575 E_(1a)E₂E_(ii)E₄ E_(vii) E₅ E_(d) 3576 E_(1b)E₂E_(ii)E₄ E_(vii) E₅ E_(d) 3577 E_(1a)E₂E_(ii)E_(iib)E₄ E_(vii) E₅ E_(d) 3578 E_(1b)E₂E_(ii)E_(iib)E₄ E_(vii) E₅ E_(d) 3579 E_(1a)E₂E₃E_(i)E₄ E_(vii) E₅ E_(d) 3580 E_(1b)E₂E₃E_(i)E₄ E_(vii) E₅ E_(d) 3581 E_(1a)E₂E₃E_(ii)E₄ E_(vii) E₅ E_(d) 3582 E_(1b)E₂E₃E_(ii)E₄ E_(vii) E₅ E_(d) 3583 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E_(vii) E₅ E_(d) 3584 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E_(vii) E₅ E_(d) 3585 E_(1a)E₂E_(iii) E_(vii) E₅ E_(d) 3586 E_(1b)E₂E_(iii) E_(vii) E₅ E_(d) 3587 E_(1a)E₂E₃E_(iii) E_(vii) E₅ E_(d) 3588 E_(1b)E₂E₃E_(iii) E_(vii) E₅ E_(d) 3589 E_(1a)E₂E_(iii)E₄ E_(vii) E₅ E_(d) 3590 E_(1b)E₂E_(iii)E₄ E_(vii) E₅ E_(d) 3591 E_(1a)E₂E₃E_(iii)E₄ E_(vii) E₅ E_(d) 3592 E_(1b)E₂E₃E_(iii)E₄ E_(vii) E₅ E_(d) 3593 E_(1a)E₂E_(iv) E_(vii) E₅ E_(d) 3594 E_(1b)E₂E_(iv) E_(vii) E₅ E_(d) 3595 E_(1a)E₂E₃E_(iv) E_(vii) E₅ E_(d) 3596 E_(1b)E₂E₃E_(iv) E_(vii) E₅ E_(d) 3597 E_(1a)E₂E_(iv)E₄ E_(vii) E₅ E_(d) 3598 E_(1b)E₂E_(iv)E₄ E_(vii) E₅ E_(d) 3599 E_(1a)E₂E₃E_(iv)E₄ E_(vii) E₅ E_(d) 3600 E_(1b)E₂E₃E_(iv)E₄ E_(vii) E₅ E_(d) 3601 E_(1a)E₂ E_(vii) E₄*E₅ E_(d) 3602 E_(1b)E₂ E_(vii) E₄*E₅ E_(d) 3603 E_(1a)E₂E₃ E_(vii) E₄*E₅ E_(d) 3604 E_(1b)E₂E₃ E_(vii) E₄*E₅ E_(d) 3605 E_(1a)E₂E_(i) E_(vii) E₄*E₅ E_(d) 3606 E_(1b)E₂E_(i) E_(vii) E₄*E₅ E_(d) 3607 E_(1a)E₂E_(ii) E_(vii) E₄*E₅ E_(d) 3608 E_(1b)E₂E_(ii) E_(vii) E₄*E₅ E_(d) 3609 E_(1a)E₂E_(ii)E_(iib) E_(vii) E₄*E₅ E_(d) 3610 E_(1b)E₂E_(ii)E_(iib) E_(vii) E₄*E₅ E_(d) 3611 E_(1a)E₂E₃E_(i) E_(vii) E₄*E₅ E_(d) 3612 E_(1b)E₂E₃E_(i) E_(vii) E₄*E₅ E_(d) 3613 E_(1a)E₂E₃E_(ii) E_(vii) E₄*E₅ E_(d) 3614 E_(1b)E₂E₃E_(ii) E_(vii) E₄*E₅ E_(d) 3615 E_(1a)E₂E₃E_(ii)E_(iib) E_(vii) E₄*E₅ E_(d) 3616 E_(1b)E₂E₃E_(ii)E_(iib) E_(vii) E₄*E₅ E_(d) 3617 E_(1a)E₂E₄ E_(vii) E₄*E₅ E_(d) 3618 E_(1b)E₂E₄ E_(vii) E₄*E₅ E_(d) 3619 E_(1a)E₂E₃E₄ E_(vii) E₄*E₅ E_(d) 3620 E_(1b)E₂E₃E₄ E_(vii) E₄*E₅ E_(d) 3621 E_(1a)E₂E_(i)E₄ E_(vii) E₄*E₅ E_(d) 3622 E_(1b)E₂E_(i)E₄ E_(vii) E₄*E₅ E_(d) 3623 E_(1a)E₂E_(ii)E₄ E_(vii) E₄*E₅ E_(d) 3624 E_(1b)E₂E_(ii)E₄ E_(vii) E₄*E₅ E_(d) 3625 E_(1a)E₂E_(ii)E_(iib)E₄ E_(vii) E₄*E₅ E_(d) 3626 E_(1b)E₂E_(ii)E_(iib)E₄ E_(vii) E₄*E₅ E_(d) 3627 E_(1a)E₂E₃E_(i)E₄ E_(vii) E₄*E₅ E_(d) 3628 E_(1b)E₂E₃E_(i)E₄ E_(vii) E₄*E₅ E_(d) 3629 E_(1a)E₂E₃E_(ii)E₄ E_(vii) E₄*E₅ E_(d) 3630 E_(1b)E₂E₃E_(ii)E₄ E_(vii) E₄*E₅ E_(d) 3631 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E_(vii) E₄*E₅ E_(d) 3632 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E_(vii) E₄*E₅ E_(d) 3633 E_(1a)E₂E_(iii) E_(vii) E₄*E₅ E_(d) 3634 E_(1b)E₂E_(iii) E_(vii) E₄*E₅ E_(d) 3635 E_(1a)E₂E₃E_(iii) E_(vii) E₄*E₅ E_(d) 3636 E_(1b)E₂E₃E_(iii) E_(vii) E₄*E₅ E_(d) 3637 E_(1a)E₂E_(iii)E₄ E_(vii) E₄*E₅ E_(d) 3638 E_(1b)E₂E_(iii)E₄ E_(vii) E₄*E₅ E_(d) 3639 E_(1a)E₂E₃E_(iii)E₄ E_(vii) E₄*E₅ E_(d) 3640 E_(1b)E₂E₃E_(iii)E₄ E_(vii) E₄*E₅ E_(d) 3641 E_(1a)E₂E_(iv) E_(vii) E₄*E₅ E_(d) 3642 E_(1b)E₂E_(iv) E_(vii) E₄*E₅ E_(d) 3643 E_(1a)E₂E₃E_(iv) E_(vii) E₄*E₅ E_(d) 3644 E_(1b)E₂E₃E_(iv) E_(vii) E₄*E₅ E_(d) 3645 E_(1a)E₂E_(iv)E₄ E_(vii) E₄*E₅ E_(d) 3646 E_(1b)E₂E_(iv)E₄ E_(vii) E₄*E₅ E_(d) 3647 E_(1a)E₂E₃E_(iv)E₄ E_(vii) E₄*E₅ E_(d) 3648 E_(1b)E₂E₃E_(iv)E₄ E_(vii) E₄*E₅ E_(d) 3649 E_(1a)E₂ AlkLE_(vii) E_(d) 3650 E_(1b)E₂ AlkLE_(vii) E_(d) 3651 E_(1a)E₂E₃ AlkLE_(vii) E_(d) 3652 E_(1b)E₂E₃ AlkLE_(vii) E_(d) 3653 E_(1a)E₂E_(i) AlkLE_(vii) E_(d) 3654 E_(1b)E₂E_(i) AlkLE_(vii) E_(d) 3655 E_(1a)E₂E_(ii) AlkLE_(vii) E_(d) 3656 E_(1b)E₂E_(ii) AlkLE_(vii) E_(d) 3657 E_(1a)E₂E_(ii)E_(iib) AlkLE_(vii) E_(d) 3658 E_(1b)E₂E_(ii)E_(iib) AlkLE_(vii) E_(d) 3659 E_(1a)E₂E₃E_(i) AlkLE_(vii) E_(d) 3660 E_(1b)E₂E₃E_(i) AlkLE_(vii) E_(d) 3661 E_(1a)E₂E₃E_(ii) AlkLE_(vii) E_(d) 3662 E_(1b)E₂E₃E_(ii) AlkLE_(vii) E_(d) 3663 E_(1a)E₂E₃E_(ii)E_(iib) AlkLE_(vii) E_(d) 3664 E_(1b)E₂E₃E_(ii)E_(iib) AlkLE_(vii) E_(d) 3665 E_(1a)E₂E₄ AlkLE_(vii) E_(d) 3666 E_(1b)E₂E₄ AlkLE_(vii) E_(d) 3667 E_(1a)E₂E₃E₄ AlkLE_(vii) E_(d) 3668 E_(1b)E₂E₃E₄ AlkLE_(vii) E_(d) 3669 E_(1a)E₂E_(i)E₄ AlkLE_(vii) E_(d) 3670 E_(1b)E₂E_(i)E₄ AlkLE_(vii) E_(d) 3671 E_(1a)E₂E_(ii)E₄ AlkLE_(vii) E_(d) 3672 E_(1b)E₂E_(ii)E₄ AlkLE_(vii) E_(d) 3673 E_(1a)E₂E_(ii)E_(iib)E₄ AlkLE_(vii) E_(d) 3674 E_(1b)E₂E_(ii)E_(iib)E₄ AlkLE_(vii) E_(d) 3675 E_(1a)E₂E₃E_(i)E₄ AlkLE_(vii) E_(d) 3676 E_(1b)E₂E₃E_(i)E₄ AlkLE_(vii) E_(d) 3677 E_(1a)E₂E₃E_(ii)E₄ AlkLE_(vii) E_(d) 3678 E_(1b)E₂E₃E_(ii)E₄ AlkLE_(vii) E_(d) 3679 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(vii) E_(d) 3680 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(vii) E_(d) 3681 E_(1a)E₂E_(iii) AlkLE_(vii) E_(d) 3682 E_(1b)E₂E_(iii) AlkLE_(vii) E_(d) 3683 E_(1a)E₂E₃E_(iii) AlkLE_(vii) E_(d) 3684 E_(1b)E₂E₃E_(iii) AlkLE_(vii) E_(d) 3685 E_(1a)E₂E_(iii)E₄ AlkLE_(vii) E_(d) 3686 E_(1b)E₂E_(iii)E₄ AlkLE_(vii) E_(d) 3687 E_(1a)E₂E₃E_(iii)E₄ AlkLE_(vii) E_(d) 3688 E_(1b)E₂E₃E_(iii)E₄ AlkLE_(vii) E_(d) 3689 E_(1a)E₂E_(iv) AlkLE_(vii) E_(d) 3690 E_(1b)E₂E_(iv) AlkLE_(vii) E_(d) 3691 E_(1a)E₂E₃E_(iv) AlkLE_(vii) E_(d) 3692 E_(1b)E₂E₃E_(iv) AlkLE_(vii) E_(d) 3693 E_(1a)E₂E_(iv)E₄ AlkLE_(vii) E_(d) 3694 E_(1b)E₂E_(iv)E₄ AlkLE_(vii) E_(d) 3695 E_(1a)E₂E₃E_(iv)E₄ AlkLE_(vii) E_(d) 3696 E_(1b)E₂E₃E_(iv)E₄ AlkLE_(vii) E_(d) 3697 E_(1a)E₂ AlkLE_(vii) E₄* E_(d) 3698 E_(1b)E₂ AlkLE_(vii) E₄* E_(d) 3699 E_(1a)E₂E₃ AlkLE_(vii) E₄* E_(d) 3700 E_(1b)E₂E₃ AlkLE_(vii) E₄* E_(d) 3701 E_(1a)E₂E_(i) AlkLE_(vii) E₄* E_(d) 3702 E_(1b)E₂E_(i) AlkLE_(vii) E₄* E_(d) 3703 E_(1a)E₂E_(ii) AlkLE_(vii) E₄* E_(d) 3704 E_(1b)E₂E_(ii) AlkLE_(vii) E₄* E_(d) 3705 E_(1a)E₂E_(ii)E_(iib) AlkLE_(vii) E₄* E_(d) 3706 E_(1b)E₂E_(ii)E_(iib) AlkLE_(vii) E₄* E_(d) 3707 E_(1a)E₂E₃E_(i) AlkLE_(vii) E₄* E_(d) 3708 E_(1b)E₂E₃E_(i) AlkLE_(vii) E₄* E_(d) 3709 E_(1a)E₂E₃E_(ii) AlkLE_(vii) E₄* E_(d) 3710 E_(1b)E₂E₃E_(ii) AlkLE_(vii) E₄* E_(d) 3711 E_(1a)E₂E₃E_(ii)E_(iib) AlkLE_(vii) E₄* E_(d) 3712 E_(1b)E₂E₃E_(ii)E_(iib) AlkLE_(vii) E₄* E_(d) 3713 E_(1a)E₂E₄ AlkLE_(vii) E₄* E_(d) 3714 E_(1b)E₂E₄ AlkLE_(vii) E₄* E_(d) 3715 E_(1a)E₂E₃E₄ AlkLE_(vii) E₄* E_(d) 3716 E_(1b)E₂E₃E₄ AlkLE_(vii) E₄* E_(d) 3717 E_(1a)E₂E_(i)E₄ AlkLE_(vii) E₄* E_(d) 3718 E_(1b)E₂E_(i)E₄ AlkLE_(vii) E₄* E_(d) 3719 E_(1a)E₂E_(ii)E₄ AlkLE_(vii) E₄* E_(d) 3720 E_(1b)E₂E_(ii)E₄ AlkLE_(vii) E₄* E_(d) 3721 E_(1a)E₂E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* E_(d) 3722 E_(1b)E₂E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* E_(d) 3723 E_(1a)E₂E₃E_(i)E₄ AlkLE_(vii) E₄* E_(d) 3724 E_(1b)E₂E₃E_(i)E₄ AlkLE_(vii) E₄* E_(d) 3725 E_(1a)E₂E₃E_(ii)E₄ AlkLE_(vii) E₄* E_(d) 3726 E_(1b)E₂E₃E_(ii)E₄ AlkLE_(vii) E₄* E_(d) 3727 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* E_(d) 3728 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* E_(d) 3729 E_(1a)E₂E_(iii) AlkLE_(vii) E₄* E_(d) 3730 E_(1b)E₂E_(iii) AlkLE_(vii) E₄* E_(d) 3731 E_(1a)E₂E₃E_(iii) AlkLE_(vii) E₄* E_(d) 3732 E_(1b)E₂E₃E_(iii) AlkLE_(vii) E₄* E_(d) 3733 E_(1a)E₂E_(iii)E₄ AlkLE_(vii) E₄* E_(d) 3734 E_(1b)E₂E_(iii)E₄ AlkLE_(vii) E₄* E_(d) 3735 E_(1a)E₂E₃E_(iii)E₄ AlkLE_(vii) E₄* E_(d) 3736 E_(1b)E₂E₃E_(iii)E₄ AlkLE_(vii) E₄* E_(d) 3737 E_(1a)E₂E_(iv) AlkLE_(vii) E₄* E_(d) 3738 E_(1b)E₂E_(iv) AlkLE_(vii) E₄* E_(d) 3739 E_(1a)E₂E₃E_(iv) AlkLE_(vii) E₄* E_(d) 3740 E_(1b)E₂E₃E_(iv) AlkLE_(vii) E₄* E_(d) 3741 E_(1a)E₂E_(iv)E₄ AlkLE_(vii) E₄* E_(d) 3742 E_(1b)E₂E_(iv)E₄ AlkLE_(vii) E₄* E_(d) 3743 E_(1a)E₂E₃E_(iv)E₄ AlkLE_(vii) E₄* E_(d) 3744 E_(1b)E₂E₃E_(iv)E₄ AlkLE_(vii) E₄* E_(d) 3745 E_(1a)E₂ AlkLE_(vii) E₅ E_(d) 3746 E_(1b)E₂ AlkLE_(vii) E₅ E_(d) 3747 E_(1a)E₂E₃ AlkLE_(vii) E₅ E_(d) 3748 E_(1b)E₂E₃ AlkLE_(vii) E₅ E_(d) 3749 E_(1a)E₂E_(i) AlkLE_(vii) E₅ E_(d) 3750 E_(1b)E₂E_(i) AlkLE_(vii) E₅ E_(d) 3751 E_(1a)E₂E_(ii) AlkLE_(vii) E₅ E_(d) 3752 E_(1b)E₂E_(ii) AlkLE_(vii) E₅ E_(d) 3753 E_(1a)E₂E_(ii)E_(iib) AlkLE_(vii) E₅ E_(d) 3754 E_(1b)E₂E_(ii)E_(iib) AlkLE_(vii) E₅ E_(d) 3755 E_(1a)E₂E₃E_(i) AlkLE_(vii) E₅ E_(d) 3756 E_(1b)E₂E₃E_(i) AlkLE_(vii) E₅ E_(d) 3757 E_(1a)E₂E₃E_(ii) AlkLE_(vii) E₅ E_(d) 3758 E_(1b)E₂E₃E_(ii) AlkLE_(vii) E₅ E_(d) 3759 E_(1a)E₂E₃E_(ii)E_(iib) AlkLE_(vii) E₅ E_(d) 3760 E_(1b)E₂E₃E_(ii)E_(iib) AlkLE_(vii) E₅ E_(d) 3761 E_(1a)E₂E₄ AlkLE_(vii) E₅ E_(d) 3762 E_(1b)E₂E₄ AlkLE_(vii) E₅ E_(d) 3763 E_(1a)E₂E₃E₄ AlkLE_(vii) E₅ E_(d) 3764 E_(1b)E₂E₃E₄ AlkLE_(vii) E₅ E_(d) 3765 E_(1a)E₂E_(i)E₄ AlkLE_(vii) E₅ E_(d) 3766 E_(1b)E₂E_(i)E₄ AlkLE_(vii) E₅ E_(d) 3767 E_(1a)E₂E_(ii)E₄ AlkLE_(vii) E₅ E_(d) 3768 E_(1b)E₂E_(ii)E₄ AlkLE_(vii) E₅ E_(d) 3769 E_(1a)E₂E_(ii)E_(iib)E₄ AlkLE_(vii) E₅ E_(d) 3770 E_(1b)E₂E_(ii)E_(iib)E₄ AlkLE_(vii) E₅ E_(d) 3771 E_(1a)E₂E₃E_(i)E₄ AlkLE_(vii) E₅ E_(d) 3772 E_(1b)E₂E₃E_(i)E₄ AlkLE_(vii) E₅ E_(d) 3773 E_(1a)E₂E₃E_(ii)E₄ AlkLE_(vii) E₅ E_(d) 3774 E_(1b)E₂E₃E_(ii)E₄ AlkLE_(vii) E₅ E_(d) 3775 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(vii) E₅ E_(d) 3776 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(vii) E₅ E_(d) 3777 E_(1a)E₂E_(iii) AlkLE_(vii) E₅ E_(d) 3778 E_(1b)E₂E_(iii) AlkLE_(vii) E₅ E_(d) 3779 E_(1a)E₂E₃E_(iii) AlkLE_(vii) E₅ E_(d) 3780 E_(1b)E₂E₃E_(iii) AlkLE_(vii) E₅ E_(d) 3781 E_(1a)E₂E_(iii)E₄ AlkLE_(vii) E₅ E_(d) 3782 E_(1b)E₂E_(iii)E₄ AlkLE_(vii) E₅ E_(d) 3783 E_(1a)E₂E₃E_(iii)E₄ AlkLE_(vii) E₅ E_(d) 3784 E_(1b)E₂E₃E_(iii)E₄ AlkLE_(vii) E₅ E_(d) 3785 E_(1a)E₂E_(iv) AlkLE_(vii) E₅ E_(d) 3786 E_(1b)E₂E_(iv) AlkLE_(vii) E₅ E_(d) 3787 E_(1a)E₂E₃E_(iv) AlkLE_(vii) E₅ E_(d) 3788 E_(1b)E₂E₃E_(iv) AlkLE_(vii) E₅ E_(d) 3789 E_(1a)E₂E_(iv)E₄ AlkLE_(vii) E₅ E_(d) 3790 E_(1b)E₂E_(iv)E₄ AlkLE_(vii) E₅ E_(d) 3791 E_(1a)E₂E₃E_(iv)E₄ AlkLE_(vii) E₅ E_(d) 3792 E_(1b)E₂E₃E_(iv)E₄ AlkLE_(vii) E₅ E_(d) 3793 E_(1a)E₂ AlkLE_(vii) E₄*E₅ E_(d) 3794 E_(1b)E₂ AlkLE_(vii) E₄*E₅ E_(d) 3795 E_(1a)E₂E₃ AlkLE_(vii) E₄*E₅ E_(d) 3796 E_(1b)E₂E₃ AlkLE_(vii) E₄*E₅ E_(d) 3797 E_(1a)E₂E_(i) AlkLE_(vii) E₄*E₅ E_(d) 3798 E_(1b)E₂E_(i) AlkLE_(vii) E₄*E₅ E_(d) 3799 E_(1a)E₂E_(ii) AlkLE_(vii) E₄*E₅ E_(d) 3800 E_(1b)E₂E_(ii) AlkLE_(vii) E₄*E₅ E_(d) 3801 E_(1a)E₂E_(ii)E_(iib) AlkLE_(vii) E₄*E₅ E_(d) 3802 E_(1b)E₂E_(ii)E_(iib) AlkLE_(vii) E₄*E₅ E_(d) 3803 E_(1a)E₂E₃E_(i) AlkLE_(vii) E₄*E₅ E_(d) 3804 E_(1b)E₂E₃E_(i) AlkLE_(vii) E₄*E₅ E_(d) 3805 E_(1a)E₂E₃E_(ii) AlkLE_(vii) E₄*E₅ E_(d) 3806 E_(1b)E₂E₃E_(ii) AlkLE_(vii) E₄*E₅ E_(d) 3807 E_(1a)E₂E₃E_(ii)E_(iib) AlkLE_(vii) E₄*E₅ E_(d) 3808 E_(1b)E₂E₃E_(ii)E_(iib) AlkLE_(vii) E₄*E₅ E_(d) 3809 E_(1a)E₂E₄ AlkLE_(vii) E₄*E₅ E_(d) 3810 E_(1b)E₂E₄ AlkLE_(vii) E₄*E₅ E_(d) 3811 E_(1a)E₂E₃E₄ AlkLE_(vii) E₄*E₅ E_(d) 3812 E_(1b)E₂E₃E₄ AlkLE_(vii) E₄*E₅ E_(d) 3813 E_(1a)E₂E_(i)E₄ AlkLE_(vii) E₄*E₅ E_(d) 3814 E_(1b)E₂E_(i)E₄ AlkLE_(vii) E₄*E₅ E_(d) 3815 E_(1a)E₂E_(ii)E₄ AlkLE_(vii) E₄*E₅ E_(d) 3816 E_(1b)E₂E_(ii)E₄ AlkLE_(vii) E₄*E₅ E_(d) 3817 E_(1a)E₂E_(ii)E_(iib)E₄ AlkLE_(vii) E₄*E₅ E_(d) 3818 E_(1b)E₂E_(ii)E_(iib)E₄ AlkLE_(vii) E₄*E₅ E_(d) 3819 E_(1a)E₂E₃E_(i)E₄ AlkLE_(vii) E₄*E₅ E_(d) 3820 E_(1b)E₂E₃E_(i)E₄ AlkLE_(vii) E₄*E₅ E_(d) 3821 E_(1a)E₂E₃E_(ii)E₄ AlkLE_(vii) E₄*E₅ E_(d) 3822 E_(1b)E₂E₃E_(ii)E₄ AlkLE_(vii) E₄*E₅ E_(d) 3823 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(vii) E₄*E₅ E_(d) 3824 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(vii) E₄*E₅ E_(d) 3825 E_(1a)E₂E_(iii) AlkLE_(vii) E₄*E₅ E_(d) 3826 E_(1b)E₂E_(iii) AlkLE_(vii) E₄*E₅ E_(d) 3827 E_(1a)E₂E₃E_(iii) AlkLE_(vii) E₄*E₅ E_(d) 3828 E_(1b)E₂E₃E_(iii) AlkLE_(vii) E₄*E₅ E_(d) 3829 E_(1a)E₂E_(iii)E₄ AlkLE_(vii) E₄*E₅ E_(d) 3830 E_(1b)E₂E_(iii)E₄ AlkLE_(vii) E₄*E₅ E_(d) 3831 E_(1a)E₂E₃E_(iii)E₄ AlkLE_(vii) E₄*E₅ E_(d) 3832 E_(1b)E₂E₃E_(iii)E₄ AlkLE_(vii) E₄*E₅ E_(d) 3833 E_(1a)E₂E_(iv) AlkLE_(vii) E₄*E₅ E_(d) 3834 E_(1b)E₂E_(iv) AlkLE_(vii) E₄*E₅ E_(d) 3835 E_(1a)E₂E₃E_(iv) AlkLE_(vii) E₄*E₅ E_(d) 3836 E_(1b)E₂E₃E_(iv) AlkLE_(vii) E₄*E₅ E_(d) 3837 E_(1a)E₂E_(iv)E₄ AlkLE_(vii) E₄*E₅ E_(d) 3838 E_(1b)E₂E_(iv)E₄ AlkLE_(vii) E₄*E₅ E_(d) 3839 E_(1a)E₂E₃E_(iv)E₄ AlkLE_(vii) E₄*E₅ E_(d) 3840 E_(1b)E₂E₃E_(iv)E₄ AlkLE_(vii) E₄*E₅ E_(d) 3841 E_(1a)E₂ E_(vii) E_(e) 3842 E_(1b)E₂ E_(vii) E_(e) 3843 E_(1a)E₂E₃ E_(vii) E_(e) 3844 E_(1b)E₂E₃ E_(vii) E_(e) 3845 E_(1a)E₂E_(i) E_(vii) E_(e) 3846 E_(1b)E₂E_(i) E_(vii) E_(e) 3847 E_(1a)E₂E_(ii) E_(vii) E_(e) 3848 E_(1b)E₂E_(ii) E_(vii) E_(e) 3849 E_(1a)E₂E_(ii)E_(iib) E_(vii) E_(e) 3850 E_(1b)E₂E_(ii)E_(iib) E_(vii) E_(e) 3851 E_(1a)E₂E₃E_(i) E_(vii) E_(e) 3852 E_(1b)E₂E₃E_(i) E_(vii) E_(e) 3853 E_(1a)E₂E₃E_(ii) E_(vii) E_(e) 3854 E_(1b)E₂E₃E_(ii) E_(vii) E_(e) 3855 E_(1a)E₂E₃E_(ii)E_(iib) E_(vii) E_(e) 3856 E_(1b)E₂E₃E_(ii)E_(iib) E_(vii) E_(e) 3857 E_(1a)E₂E₄ E_(vii) E_(e) 3858 E_(1b)E₂E₄ E_(vii) E_(e) 3859 E_(1a)E₂E₃E₄ E_(vii) E_(e) 3860 E_(1b)E₂E₃E₄ E_(vii) E_(e) 3861 E_(1a)E₂E_(i)E₄ E_(vii) E_(e) 3862 E_(1b)E₂E_(i)E₄ E_(vii) E_(e) 3863 E_(1a)E₂E_(ii)E₄ E_(vii) E_(e) 3864 E_(1b)E₂E_(ii)E₄ E_(vii) E_(e) 3865 E_(1a)E₂E_(ii)E_(iib)E₄ E_(vii) E_(e) 3866 E_(1b)E₂E_(ii)E_(iib)E₄ E_(vii) E_(e) 3867 E_(1a)E₂E₃E_(i)E₄ E_(vii) E_(e) 3868 E_(1b)E₂E₃E_(i)E₄ E_(vii) E_(e) 3869 E_(1a)E₂E₃E_(ii)E₄ E_(vii) E_(e) 3870 E_(1b)E₂E₃E_(ii)E₄ E_(vii) E_(e) 3871 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E_(vii) E_(e) 3872 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E_(vii) E_(e) 3873 E_(1a)E₂E_(iii) E_(vii) E_(e) 3874 E_(1b)E₂E_(iii) E_(vii) E_(e) 3875 E_(1a)E₂E₃E_(iii) E_(vii) E_(e) 3876 E_(1b)E₂E₃E_(iii) E_(vii) E_(e) 3877 E_(1a)E₂E_(iii)E₄ E_(vii) E_(e) 3878 E_(1b)E₂E_(iii)E₄ E_(vii) E_(e) 3879 E_(1a)E₂E₃E_(iii)E₄ E_(vii) E_(e) 3880 E_(1b)E₂E₃E_(iii)E₄ E_(vii) E_(e) 3881 E_(1a)E₂E_(iv) E_(vii) E_(e) 3882 E_(1b)E₂E_(iv) E_(vii) E_(e) 3883 E_(1a)E₂E₃E_(iv) E_(vii) E_(e) 3884 E_(1b)E₂E₃E_(iv) E_(vii) E_(e) 3885 E_(1a)E₂E_(iv)E₄ E_(vii) E_(e) 3886 E_(1b)E₂E_(iv)E₄ E_(vii) E_(e) 3887 E_(1a)E₂E₃E_(iv)E₄ E_(vii) E_(e) 3888 E_(1b)E₂E₃E_(iv)E₄ E_(vii) E_(e) 3889 E_(1a)E₂ E_(vii) E₄* E_(e) 3890 E_(1b)E₂ E_(vii) E₄* E_(e) 3891 E_(1a)E₂E₃ E_(vii) E₄* E_(e) 3892 E_(1b)E₂E₃ E_(vii) E₄* E_(e) 3893 E_(1a)E₂E_(i) E_(vii) E₄* E_(e) 3894 E_(1b)E₂E_(i) E_(vii) E₄* E_(e) 3895 E_(1a)E₂E_(ii) E_(vii) E₄* E_(e) 3896 E_(1b)E₂E_(ii) E_(vii) E₄* E_(e) 3897 E_(1a)E₂E_(ii)E_(iib) E_(vii) E₄* E_(e) 3898 E_(1b)E₂E_(ii)E_(iib) E_(vii) E₄* E_(e) 3899 E_(1a)E₂E₃E_(i) E_(vii) E₄* E_(e) 3900 E_(1b)E₂E₃E_(i) E_(vii) E₄* E_(e) 3901 E_(1a)E₂E₃E_(ii) E_(vii) E₄* E_(e) 3902 E_(1b)E₂E₃E_(ii) E_(vii) E₄* E_(e) 3903 E_(1a)E₂E₃E_(ii)E_(iib) E_(vii) E₄* E_(e) 3904 E_(1b)E₂E₃E_(ii)E_(iib) E_(vii) E₄* E_(e) 3905 E_(1a)E₂E₄ E_(vii) E₄* E_(e) 3906 E_(1b)E₂E₄ E_(vii) E₄* E_(e) 3907 E_(1a)E₂E₃E₄ E_(vii) E₄* E_(e) 3908 E_(1b)E₂E₃E₄ E_(vii) E₄* E_(e) 3909 E_(1a)E₂E_(i)E₄ E_(vii) E₄* E_(e) 3910 E_(1b)E₂E_(i)E₄ E_(vii) E₄* E_(e) 3911 E_(1a)E₂E_(ii)E₄ E_(vii) E₄* E_(e) 3912 E_(1b)E₂E_(ii)E₄ E_(vii) E₄* E_(e) 3913 E_(1a)E₂E_(ii)E_(iib)E₄ E_(vii) E₄* E_(e) 3914 E_(1b)E₂E_(ii)E_(iib)E₄ E_(vii) E₄* E_(e) 3915 E_(1a)E₂E₃E_(i)E₄ E_(vii) E₄* E_(e) 3916 E_(1b)E₂E₃E_(i)E₄ E_(vii) E₄* E_(e) 3917 E_(1a)E₂E₃E_(ii)E₄ E_(vii) E₄* E_(e) 3918 E_(1b)E₂E₃E_(ii)E₄ E_(vii) E₄* E_(e) 3919 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E_(vii) E₄* E_(e) 3920 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E_(vii) E₄* E_(e) 3921 E_(1a)E₂E_(iii) E_(vii) E₄* E_(e) 3922 E_(1b)E₂E_(iii) E_(vii) E₄* E_(e) 3923 E_(1a)E₂E₃E_(iii) E_(vii) E₄* E_(e) 3924 E_(1b)E₂E₃E_(iii) E_(vii) E₄* E_(e) 3925 E_(1a)E₂E_(iii)E₄ E_(vii) E₄* E_(e) 3926 E_(1b)E₂E_(iii)E₄ E_(vii) E₄* E_(e) 3927 E_(1a)E₂E₃E_(iii)E₄ E_(vii) E₄* E_(e) 3928 E_(1b)E₂E₃E_(iii)E₄ E_(vii) E₄* E_(e) 3929 E_(1a)E₂E_(iv) E_(vii) E₄* E_(e) 3930 E_(1b)E₂E_(iv) E_(vii) E₄* E_(e) 3931 E_(1a)E₂E₃E_(iv) E_(vii) E₄* E_(e) 3932 E_(1b)E₂E₃E_(iv) E_(vii) E₄* E_(e) 3933 E_(1a)E₂E_(iv)E₄ E_(vii) E₄* E_(e) 3934 E_(1b)E₂E_(iv)E₄ E_(vii) E₄* E_(e) 3935 E_(1a)E₂E₃E_(iv)E₄ E_(vii) E₄* E_(e) 3936 E_(1b)E₂E₃E_(iv)E₄ E_(vii) E₄* E_(e) 3937 E_(1a)E₂ E_(vii) E₅ E_(e) 3938 E_(1b)E₂ E_(vii) E₅ E_(e) 3939 E_(1a)E₂E₃ E_(vii) E₅ E_(e) 3940 E_(1b)E₂E₃ E_(vii) E₅ E_(e) 3941 E_(1a)E₂E_(i) E_(vii) E₅ E_(e) 3942 E_(1b)E₂E_(i) E_(vii) E₅ E_(e) 3943 E_(1a)E₂E_(ii) E_(vii) E₅ E_(e) 3944 E_(1b)E₂E_(ii) E_(vii) E₅ E_(e) 3945 E_(1a)E₂E_(ii)E_(iib) E_(vii) E₅ E_(e) 3946 E_(1b)E₂E_(ii)E_(iib) E_(vii) E₅ E_(e) 3947 E_(1a)E₂E₃E_(i) E_(vii) E₅ E_(e) 3948 E_(1b)E₂E₃E_(i) E_(vii) E₅ E_(e) 3949 E_(1a)E₂E₃E_(ii) E_(vii) E₅ E_(e) 3950 E_(1b)E₂E₃E_(ii) E_(vii) E₅ E_(e) 3951 E_(1a)E₂E₃E_(ii)E_(iib) E_(vii) E₅ E_(e) 3952 E_(1b)E₂E₃E_(ii)E_(iib) E_(vii) E₅ E_(e) 3953 E_(1a)E₂E₄ E_(vii) E₅ E_(e) 3954 E_(1b)E₂E₄ E_(vii) E₅ E_(e) 3955 E_(1a)E₂E₃E₄ E_(vii) E₅ E_(e) 3956 E_(1b)E₂E₃E₄ E_(vii) E₅ E_(e) 3957 E_(1a)E₂E_(i)E₄ E_(vii) E₅ E_(e) 3958 E_(1b)E₂E_(i)E₄ E_(vii) E₅ E_(e) 3959 E_(1a)E₂E_(ii)E₄ E_(vii) E₅ E_(e) 3960 E_(1b)E₂E_(ii)E₄ E_(vii) E₅ E_(e) 3961 E_(1a)E₂E_(ii)E_(iib)E₄ E_(vii) E₅ E_(e) 3962 E_(1b)E₂E_(ii)E_(iib)E₄ E_(vii) E₅ E_(e) 3963 E_(1a)E₂E₃E_(i)E₄ E_(vii) E₅ E_(e) 3964 E_(1b)E₂E₃E_(i)E₄ E_(vii) E₅ E_(e) 3965 E_(1a)E₂E₃E_(ii)E₄ E_(vii) E₅ E_(e) 3966 E_(1b)E₂E₃E_(ii)E₄ E_(vii) E₅ E_(e) 3967 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E_(vii) E₅ E_(e) 3968 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E_(vii) E₅ E_(e) 3969 E_(1a)E₂E_(iii) E_(vii) E₅ E_(e) 3970 E_(1b)E₂E_(iii) E_(vii) E₅ E_(e) 3971 E_(1a)E₂E₃E_(iii) E_(vii) E₅ E_(e) 3972 E_(1b)E₂E₃E_(iii) E_(vii) E₅ E_(e) 3973 E_(1a)E₂E_(iii)E₄ E_(vii) E₅ E_(e) 3974 E_(1b)E₂E_(iii)E₄ E_(vii) E₅ E_(e) 3975 E_(1a)E₂E₃E_(iii)E₄ E_(vii) E₅ E_(e) 3976 E_(1b)E₂E₃E_(iii)E₄ E_(vii) E₅ E_(e) 3977 E_(1a)E₂E_(iv) E_(vii) E₅ E_(e) 3978 E_(1b)E₂E_(iv) E_(vii) E₅ E_(e) 3979 E_(1a)E₂E₃E_(iv) E_(vii) E₅ E_(e) 3980 E_(1b)E₂E₃E_(iv) E_(vii) E₅ E_(e) 3981 E_(1a)E₂E_(iv)E₄ E_(vii) E₅ E_(e) 3982 E_(1b)E₂E_(iv)E₄ E_(vii) E₅ E_(e) 3983 E_(1a)E₂E₃E_(iv)E₄ E_(vii) E₅ E_(e) 3984 E_(1b)E₂E₃E_(iv)E₄ E_(vii) E₅ E_(e) 3985 E_(1a)E₂ E_(vii) E₄*E₅ E_(e) 3986 E_(1b)E₂ E_(vii) E₄*E₅ E_(e) 3987 E_(1a)E₂E₃ E_(vii) E₄*E₅ E_(e) 3988 E_(1b)E₂E₃ E_(vii) E₄*E₅ E_(e) 3989 E_(1a)E₂E_(i) E_(vii) E₄*E₅ E_(e) 3990 E_(1b)E₂E_(i) E_(vii) E₄*E₅ E_(e) 3991 E_(1a)E₂E_(ii) E_(vii) E₄*E₅ E_(e) 3992 E_(1b)E₂E_(ii) E_(vii) E₄*E₅ E_(e) 3993 E_(1a)E₂E_(ii)E_(iib) E_(vii) E₄*E₅ E_(e) 3994 E_(1b)E₂E_(ii)E_(iib) E_(vii) E₄*E₅ E_(e) 3995 E_(1a)E₂E₃E_(i) E_(vii) E₄*E₅ E_(e) 3996 E_(1b)E₂E₃E_(i) E_(vii) E₄*E₅ E_(e) 3997 E_(1a)E₂E₃E_(ii) E_(vii) E₄*E₅ E_(e) 3998 E_(1b)E₂E₃E_(ii) E_(vii) E₄*E₅ E_(e) 3999 E_(1a)E₂E₃E_(ii)E_(iib) E_(vii) E₄*E₅ E_(e) 4000 E_(1b)E₂E₃E_(ii)E_(iib) E_(vii) E₄*E₅ E_(e) 4001 E_(1a)E₂E₄ E_(vii) E₄*E₅ E_(e) 4002 E_(1b)E₂E₄ E_(vii) E₄*E₅ E_(e) 4003 E_(1a)E₂E₃E₄ E_(vii) E₄*E₅ E_(e) 4004 E_(1b)E₂E₃E₄ E_(vii) E₄*E₅ E_(e) 4005 E_(1a)E₂E_(i)E₄ E_(vii) E₄*E₅ E_(e) 4006 E_(1b)E₂E_(i)E₄ E_(vii) E₄*E₅ E_(e) 4007 E_(1a)E₂E_(ii)E₄ E_(vii) E₄*E₅ E_(e) 4008 E_(1b)E₂E_(ii)E₄ E_(vii) E₄*E₅ E_(e) 4009 E_(1a)E₂E_(ii)E_(iib)E₄ E_(vii) E₄*E₅ E_(e) 4010 E_(1b)E₂E_(ii)E_(iib)E₄ E_(vii) E₄*E₅ E_(e) 4011 E_(1a)E₂E₃E_(i)E₄ E_(vii) E₄*E₅ E_(e) 4012 E_(1b)E₂E₃E_(i)E₄ E_(vii) E₄*E₅ E_(e) 4013 E_(1a)E₂E₃E_(ii)E₄ E_(vii) E₄*E₅ E_(e) 4014 E_(1b)E₂E₃E_(ii)E₄ E_(vii) E₄*E₅ E_(e) 4015 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E_(vii) E₄*E₅ E_(e) 4016 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E_(vii) E₄*E₅ E_(e) 4017 E_(1a)E₂E_(iii) E_(vii) E₄*E₅ E_(e) 4018 E_(1b)E₂E_(iii) E_(vii) E₄*E₅ E_(e) 4019 E_(1a)E₂E₃E_(iii) E_(vii) E₄*E₅ E_(e) 4020 E_(1b)E₂E₃E_(iii) E_(vii) E₄*E₅ E_(e) 4021 E_(1a)E₂E_(iii)E₄ E_(vii) E₄*E₅ E_(e) 4022 E_(1b)E₂E_(iii)E₄ E_(vii) E₄*E₅ E_(e) 4023 E_(1a)E₂E₃E_(iii)E₄ E_(vii) E₄*E₅ E_(e) 4024 E_(1b)E₂E₃E_(iii)E₄ E_(vii) E₄*E₅ E_(e) 4025 E_(1a)E₂E_(iv) E_(vii) E₄*E₅ E_(e) 4026 E_(1b)E₂E_(iv) E_(vii) E₄*E₅ E_(e) 4027 E_(1a)E₂E₃E_(iv) E_(vii) E₄*E₅ E_(e) 4028 E_(1b)E₂E₃E_(iv) E_(vii) E₄*E₅ E_(e) 4029 E_(1a)E₂E_(iv)E₄ E_(vii) E₄*E₅ E_(e) 4030 E_(1b)E₂E_(iv)E₄ E_(vii) E₄*E₅ E_(e) 4031 E_(1a)E₂E₃E_(iv)E₄ E_(vii) E₄*E₅ E_(e) 4032 E_(1b)E₂E₃E_(iv)E₄ E_(vii) E₄*E₅ E_(e) 4033 E_(1a)E₂ AlkLE_(vii) E_(e) 4034 E_(1b)E₂ AlkLE_(vii) E_(e) 4035 E_(1a)E₂E₃ AlkLE_(vii) E_(e) 4036 E_(1b)E₂E₃ AlkLE_(vii) E_(e) 4037 E_(1a)E₂E_(i) AlkLE_(vii) E_(e) 4038 E_(1b)E₂E_(i) AlkLE_(vii) E_(e) 4039 E_(1a)E₂E_(ii) AlkLE_(vii) E_(e) 4040 E_(1b)E₂E_(ii) AlkLE_(vii) E_(e) 4041 E_(1a)E₂E_(ii)E_(iib) AlkLE_(vii) E_(e) 4042 E_(1b)E₂E_(ii)E_(iib) AlkLE_(vii) E_(e) 4043 E_(1a)E₂E₃E_(i) AlkLE_(vii) E_(e) 4044 E_(1b)E₂E₃E_(i) AlkLE_(vii) E_(e) 4045 E_(1a)E₂E₃E_(ii) AlkLE_(vii) E_(e) 4046 E_(1b)E₂E₃E_(ii) AlkLE_(vii) E_(e) 4047 E_(1a)E₂E₃E_(ii)E_(iib) AlkLE_(vii) E_(e) 4048 E_(1b)E₂E₃E_(ii)E_(iib) AlkLE_(vii) E_(e) 4049 E_(1a)E₂E₄ AlkLE_(vii) E_(e) 4050 E_(1b)E₂E₄ AlkLE_(vii) E_(e) 4051 E_(1a)E₂E₃E₄ AlkLE_(vii) E_(e) 4052 E_(1b)E₂E₃E₄ AlkLE_(vii) E_(e) 4053 E_(1a)E₂E_(i)E₄ AlkLE_(vii) E_(e) 4054 E_(1b)E₂E_(i)E₄ AlkLE_(vii) E_(e) 4055 E_(1a)E₂E_(ii)E₄ AlkLE_(vii) E_(e) 4056 E_(1b)E₂E_(ii)E₄ AlkLE_(vii) E_(e) 4057 E_(1a)E₂E_(ii)E_(iib)E₄ AlkLE_(vii) E_(e) 4058 E_(1b)E₂E_(ii)E_(iib)E₄ AlkLE_(vii) E_(e) 4059 E_(1a)E₂E₃E_(i)E₄ AlkLE_(vii) E_(e) 4060 E_(1b)E₂E₃E_(i)E₄ AlkLE_(vii) E_(e) 4061 E_(1a)E₂E₃E_(ii)E₄ AlkLE_(vii) E_(e) 4062 E_(1b)E₂E₃E_(ii)E₄ AlkLE_(vii) E_(e) 4063 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(vii) E_(e) 4064 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(vii) E_(e) 4065 E_(1a)E₂E_(iii) AlkLE_(vii) E_(e) 4066 E_(1b)E₂E_(iii) AlkLE_(vii) E_(e) 4067 E_(1a)E₂E₃E_(iii) AlkLE_(vii) E_(e) 4068 E_(1b)E₂E₃E_(iii) AlkLE_(vii) E_(e) 4069 E_(1a)E₂E_(iii)E₄ AlkLE_(vii) E_(e) 4070 E_(1b)E₂E_(iii)E₄ AlkLE_(vii) E_(e) 4071 E_(1a)E₂E₃E_(iii)E₄ AlkLE_(vii) E_(e) 4072 E_(1b)E₂E₃E_(iii)E₄ AlkLE_(vii) E_(e) 4073 E_(1a)E₂E_(iv) AlkLE_(vii) E_(e) 4074 E_(1b)E₂E_(iv) AlkLE_(vii) E_(e) 4075 E_(1a)E₂E₃E_(iv) AlkLE_(vii) E_(e) 4076 E_(1b)E₂E₃E_(iv) AlkLE_(vii) E_(e) 4077 E_(1a)E₂E_(iv)E₄ AlkLE_(vii) E_(e) 4078 E_(1b)E₂E_(iv)E₄ AlkLE_(vii) E_(e) 4079 E_(1a)E₂E₃E_(iv)E₄ AlkLE_(vii) E_(e) 4080 E_(1b)E₂E₃E_(iv)E₄ AlkLE_(vii) E_(e) 4081 E_(1a)E₂ AlkLE_(vii) E₄* E_(e) 4082 E_(1b)E₂ AlkLE_(vii) E₄* E_(e) 4083 E_(1a)E₂E₃ AlkLE_(vii) E₄* E_(e) 4084 E_(1b)E₂E₃ AlkLE_(vii) E₄* E_(e) 4085 E_(1a)E₂E_(i) AlkLE_(vii) E₄* E_(e) 4086 E_(1b)E₂E_(i) AlkLE_(vii) E₄* E_(e) 4087 E_(1a)E₂E_(ii) AlkLE_(vii) E₄* E_(e) 4088 E_(1b)E₂E_(ii) AlkLE_(vii) E₄* E_(e) 4089 E_(1a)E₂E_(ii)E_(iib) AlkLE_(vii) E₄* E_(e) 4090 E_(1b)E₂E_(ii)E_(iib) AlkLE_(vii) E₄* E_(e) 4091 E_(1a)E₂E₃E_(i) AlkLE_(vii) E₄* E_(e) 4092 E_(1b)E₂E₃E_(i) AlkLE_(vii) E₄* E_(e) 4093 E_(1a)E₂E₃E_(ii) AlkLE_(vii) E₄* E_(e) 4094 E_(1b)E₂E₃E_(ii) AlkLE_(vii) E₄* E_(e) 4095 E_(1a)E₂E₃E_(ii)E_(iib) AlkLE_(vii) E₄* E_(e) 4096 E_(1b)E₂E₃E_(ii)E_(iib) AlkLE_(vii) E₄* E_(e) 4097 E_(1a)E₂E₄ AlkLE_(vii) E₄* E_(e) 4098 E_(1b)E₂E₄ AlkLE_(vii) E₄* E_(e) 4099 E_(1a)E₂E₃E₄ AlkLE_(vii) E₄* E_(e) 4100 E_(1b)E₂E₃E₄ AlkLE_(vii) E₄* E_(e) 4101 E_(1a)E₂E_(i)E₄ AlkLE_(vii) E₄* E_(e) 4102 E_(1b)E₂E_(i)E₄ AlkLE_(vii) E₄* E_(e) 4103 E_(1a)E₂E_(ii)E₄ AlkLE_(vii) E₄* E_(e) 4104 E_(1b)E₂E_(ii)E₄ AlkLE_(vii) E₄* E_(e) 4105 E_(1a)E₂E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* E_(e) 4106 E_(1b)E₂E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* E_(e) 4107 E_(1a)E₂E₃E_(i)E₄ AlkLE_(vii) E₄* E_(e) 4108 E_(1b)E₂E₃E_(i)E₄ AlkLE_(vii) E₄* E_(e) 4109 E_(1a)E₂E₃E_(ii)E₄ AlkLE_(vii) E₄* E_(e) 4110 E_(1b)E₂E₃E_(ii)E₄ AlkLE_(vii) E₄* E_(e) 4111 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* E_(e) 4112 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* E_(e) 4113 E_(1a)E₂E_(iii) AlkLE_(vii) E₄* E_(e) 4114 E_(1b)E₂E_(iii) AlkLE_(vii) E₄* E_(e) 4115 E_(1a)E₂E₃E_(iii) AlkLE_(vii) E₄* E_(e) 4116 E_(1b)E₂E₃E_(iii) AlkLE_(vii) E₄* E_(e) 4117 E_(1a)E₂E_(iii)E₄ AlkLE_(vii) E₄* E_(e) 4118 E_(1b)E₂E_(iii)E₄ AlkLE_(vii) E₄* E_(e) 4119 E_(1a)E₂E₃E_(iii)E₄ AlkLE_(vii) E₄* E_(e) 4120 E_(1b)E₂E₃E_(iii)E₄ AlkLE_(vii) E₄* E_(e) 4121 E_(1a)E₂E_(iv) AlkLE_(vii) E₄* E_(e) 4122 E_(1b)E₂E_(iv) AlkLE_(vii) E₄* E_(e) 4123 E_(1a)E₂E₃E_(iv) AlkLE_(vii) E₄* E_(e) 4124 E_(1b)E₂E₃E_(iv) AlkLE_(vii) E₄* E_(e) 4125 E_(1a)E₂E_(iv)E₄ AlkLE_(vii) E₄* E_(e) 4126 E_(1b)E₂E_(iv)E₄ AlkLE_(vii) E₄* E_(e) 4127 E_(1a)E₂E₃E_(iv)E₄ AlkLE_(vii) E₄* E_(e) 4128 E_(1b)E₂E₃E_(iv)E₄ AlkLE_(vii) E₄* E_(e) 4129 E_(1a)E₂ AlkLE_(vii) E₅ E_(e) 4130 E_(1b)E₂ AlkLE_(vii) E₅ E_(e) 4131 E_(1a)E₂E₃ AlkLE_(vii) E₅ E_(e) 4132 E_(1b)E₂E₃ AlkLE_(vii) E₅ E_(e) 4133 E_(1a)E₂E_(i) AlkLE_(vii) E₅ E_(e) 4134 E_(1b)E₂E_(i) AlkLE_(vii) E₅ E_(e) 4135 E_(1a)E₂E_(ii) AlkLE_(vii) E₅ E_(e) 4136 E_(1b)E₂E_(ii) AlkLE_(vii) E₅ E_(e) 4137 E_(1a)E₂E_(ii)E_(iib) AlkLE_(vii) E₅ E_(e) 4138 E_(1b)E₂E_(ii)E_(iib) AlkLE_(vii) E₅ E_(e) 4139 E_(1a)E₂E₃E_(i) AlkLE_(vii) E₅ E_(e) 4140 E_(1b)E₂E₃E_(i) AlkLE_(vii) E₅ E_(e) 4141 E_(1a)E₂E₃E_(ii) AlkLE_(vii) E₅ E_(e) 4142 E_(1b)E₂E₃E_(ii) AlkLE_(vii) E₅ E_(e) 4143 E_(1a)E₂E₃E_(ii)E_(iib) AlkLE_(vii) E₅ E_(e) 4144 E_(1b)E₂E₃E_(ii)E_(iib) AlkLE_(vii) E₅ E_(e) 4145 E_(1a)E₂E₄ AlkLE_(vii) E₅ E_(e) 4146 E_(1b)E₂E₄ AlkLE_(vii) E₅ E_(e) 4147 E_(1a)E₂E₃E₄ AlkLE_(vii) E₅ E_(e) 4148 E_(1b)E₂E₃E₄ AlkLE_(vii) E₅ E_(e) 4149 E_(1a)E₂E_(i)E₄ AlkLE_(vii) E₅ E_(e) 4150 E_(1b)E₂E_(i)E₄ AlkLE_(vii) E₅ E_(e) 4151 E_(1a)E₂E_(ii)E₄ AlkLE_(vii) E₅ E_(e) 4152 E_(1b)E₂E_(ii)E₄ AlkLE_(vii) E₅ E_(e) 4153 E_(1a)E₂E_(ii)E_(iib)E₄ AlkLE_(vii) E₅ E_(e) 4154 E_(1b)E₂E_(ii)E_(iib)E₄ AlkLE_(vii) E₅ E_(e) 4155 E_(1a)E₂E₃E_(i)E₄ AlkLE_(vii) E₅ E_(e) 4156 E_(1b)E₂E₃E_(i)E₄ AlkLE_(vii) E₅ E_(e) 4157 E_(1a)E₂E₃E_(ii)E₄ AlkLE_(vii) E₅ E_(e) 4158 E_(1b)E₂E₃E_(ii)E₄ AlkLE_(vii) E₅ E_(e) 4159 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(vii) E₅ E_(e) 4160 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(vii) E₅ E_(e) 4161 E_(1a)E₂E_(iii) AlkLE_(vii) E₅ E_(e) 4162 E_(1b)E₂E_(iii) AlkLE_(vii) E₅ E_(e) 4163 E_(1a)E₂E₃E_(iii) AlkLE_(vii) E₅ E_(e) 4164 E_(1b)E₂E₃E_(iii) AlkLE_(vii) E₅ E_(e) 4165 E_(1a)E₂E_(iii)E₄ AlkLE_(vii) E₅ E_(e) 4166 E_(1b)E₂E_(iii)E₄ AlkLE_(vii) E₅ E_(e) 4167 E_(1a)E₂E₃E_(iii)E₄ AlkLE_(vii) E₅ E_(e) 4168 E_(1b)E₂E₃E_(iii)E₄ AlkLE_(vii) E₅ E_(e) 4169 E_(1a)E₂E_(iv) AlkLE_(vii) E₅ E_(e) 4170 E_(1b)E₂E_(iv) AlkLE_(vii) E₅ E_(e) 4171 E_(1a)E₂E₃E_(iv) AlkLE_(vii) E₅ E_(e) 4172 E_(1b)E₂E₃E_(iv) AlkLE_(vii) E₅ E_(e) 4173 E_(1a)E₂E_(iv)E₄ AlkLE_(vii) E₅ E_(e) 4174 E_(1b)E₂E_(iv)E₄ AlkLE_(vii) E₅ E_(e) 4175 E_(1a)E₂E₃E_(iv)E₄ AlkLE_(vii) E₅ E_(e) 4176 E_(1b)E₂E₃E_(iv)E₄ AlkLE_(vii) E₅ E_(e) 4177 E_(1a)E₂ AlkLE_(vii) E₄*E₅ E_(e) 4178 E_(1b)E₂ AlkLE_(vii) E₄*E₅ E_(e) 4179 E_(1a)E₂E₃ AlkLE_(vii) E₄*E₅ E_(e) 4180 E_(1b)E₂E₃ AlkLE_(vii) E₄*E₅ E_(e) 4181 E_(1a)E₂E_(i) AlkLE_(vii) E₄*E₅ E_(e) 4182 E_(1b)E₂E_(i) AlkLE_(vii) E₄*E₅ E_(e) 4183 E_(1a)E₂E_(ii) AlkLE_(vii) E₄*E₅ E_(e) 4184 E_(1b)E₂E_(ii) AlkLE_(vii) E₄*E₅ E_(e) 4185 E_(1a)E₂E_(ii)E_(iib) AlkLE_(vii) E₄*E₅ E_(e) 4186 E_(1b)E₂E_(ii)E_(iib) AlkLE_(vii) E₄*E₅ E_(e) 4187 E_(1a)E₂E₃E_(i) AlkLE_(vii) E₄*E₅ E_(e) 4188 E_(1b)E₂E₃E_(i) AlkLE_(vii) E₄*E₅ E_(e) 4189 E_(1a)E₂E₃E_(ii) AlkLE_(vii) E₄*E₅ E_(e) 4190 E_(1b)E₂E₃E_(ii) AlkLE_(vii) E₄*E₅ E_(e) 4191 E_(1a)E₂E₃E_(ii)E_(iib) AlkLE_(vii) E₄*E₅ E_(e) 4192 E_(1b)E₂E₃E_(ii)E_(iib) AlkLE_(vii) E₄*E₅ E_(e) 4193 E_(1a)E₂E₄ AlkLE_(vii) E₄*E₅ E_(e) 4194 E_(1b)E₂E₄ AlkLE_(vii) E₄*E₅ E_(e) 4195 E_(1a)E₂E₃E₄ AlkLE_(vii) E₄*E₅ E_(e) 4196 E_(1b)E₂E₃E₄ AlkLE_(vii) E₄*E₅ E_(e) 4197 E_(1a)E₂E_(i)E₄ AlkLE_(vii) E₄*E₅ E_(e) 4198 E_(1b)E₂E_(i)E₄ AlkLE_(vii) E₄*E₅ E_(e) 4199 E_(1a)E₂E_(ii)E₄ AlkLE_(vii) E₄*E₅ E_(e) 4200 E_(1b)E₂E_(ii)E₄ AlkLE_(vii) E₄*E₅ E_(e) 4201 E_(1a)E₂E_(ii)E_(iib)E₄ AlkLE_(vii) E₄*E₅ E_(e) 4202 E_(1b)E₂E_(ii)E_(iib)E₄ AlkLE_(vii) E₄*E₅ E_(e) 4203 E_(1a)E₂E₃E_(i)E₄ AlkLE_(vii) E₄*E₅ E_(e) 4204 E_(1b)E₂E₃E_(i)E₄ AlkLE_(vii) E₄*E₅ E_(e) 4205 E_(1a)E₂E₃E_(ii)E₄ AlkLE_(vii) E₄*E₅ E_(e) 4206 E_(1b)E₂E₃E_(ii)E₄ AlkLE_(vii) E₄*E₅ E_(e) 4207 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(vii) E₄*E₅ E_(e) 4208 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(vii) E₄*E₅ E_(e) 4209 E_(1a)E₂E_(iii) AlkLE_(vii) E₄*E₅ E_(e) 4210 E_(1b)E₂E_(iii) AlkLE_(vii) E₄*E₅ E_(e) 4211 E_(1a)E₂E₃E_(iii) AlkLE_(vii) E₄*E₅ E_(e) 4212 E_(1b)E₂E₃E_(iii) AlkLE_(vii) E₄*E₅ E_(e) 4213 E_(1a)E₂E_(iii)E₄ AlkLE_(vii) E₄*E₅ E_(e) 4214 E_(1b)E₂E_(iii)E₄ AlkLE_(vii) E₄*E₅ E_(e) 4215 E_(1a)E₂E₃E_(iii)E₄ AlkLE_(vii) E₄*E₅ E_(e) 4216 E_(1b)E₂E₃E_(iii)E₄ AlkLE_(vii) E₄*E₅ E_(e) 4217 E_(1a)E₂E_(iv) AlkLE_(vii) E₄*E₅ E_(e) 4218 E_(1b)E₂E_(iv) AlkLE_(vii) E₄*E₅ E_(e) 4219 E_(1a)E₂E₃E_(iv) AlkLE_(vii) E₄*E₅ E_(e) 4220 E_(1b)E₂E₃E_(iv) AlkLE_(vii) E₄*E₅ E_(e) 4221 E_(1a)E₂E_(iv)E₄ AlkLE_(vii) E₄*E₅ E_(e) 4222 E_(1b)E₂E_(iv)E₄ AlkLE_(vii) E₄*E₅ E_(e) 4223 E_(1a)E₂E₃E_(iv)E₄ AlkLE_(vii) E₄*E₅ E_(e) 4224 E_(1b)E₂E₃E_(iv)E₄ AlkLE_(vii) E₄*E₅ E_(e) 4225 E_(1a)E₂ E_(vii) E_(f) 4226 E_(1b)E₂ E_(vii) E_(f) 4227 E_(1a)E₂E₃ E_(vii) E_(f) 4228 E_(1b)E₂E₃ E_(vii) E_(f) 4229 E_(1a)E₂E_(i) E_(vii) E_(f) 4230 E_(1b)E₂E_(i) E_(vii) E_(f) 4231 E_(1a)E₂E_(ii) E_(vii) E_(f) 4232 E_(1b)E₂E_(ii) E_(vii) E_(f) 4233 E_(1a)E₂E_(ii)E_(iib) E_(vii) E_(f) 4234 E_(1b)E₂E_(ii)E_(iib) E_(vii) E_(f) 4235 E_(1a)E₂E₃E_(i) E_(vii) E_(f) 4236 E_(1b)E₂E₃E_(i) E_(vii) E_(f) 4237 E_(1a)E₂E₃E_(ii) E_(vii) E_(f) 4238 E_(1b)E₂E₃E_(ii) E_(vii) E_(f) 4239 E_(1a)E₂E₃E_(ii)E_(iib) E_(vii) E_(f) 4240 E_(1b)E₂E₃E_(ii)E_(iib) E_(vii) E_(f) 4241 E_(1a)E₂E₄ E_(vii) E_(f) 4242 E_(1b)E₂E₄ E_(vii) E_(f) 4243 E_(1a)E₂E₃E₄ E_(vii) E_(f) 4244 E_(1b)E₂E₃E₄ E_(vii) E_(f) 4245 E_(1a)E₂E_(i)E₄ E_(vii) E_(f) 4246 E_(1b)E₂E_(i)E₄ E_(vii) E_(f) 4247 E_(1a)E₂E_(ii)E₄ E_(vii) E_(f) 4248 E_(1b)E₂E_(ii)E₄ E_(vii) E_(f) 4249 E_(1a)E₂E_(ii)E_(iib)E₄ E_(vii) E_(f) 4250 E_(1b)E₂E_(ii)E_(iib)E₄ E_(vii) E_(f) 4251 E_(1a)E₂E₃E_(i)E₄ E_(vii) E_(f) 4252 E_(1b)E₂E₃E_(i)E₄ E_(vii) E_(f) 4253 E_(1a)E₂E₃E_(ii)E₄ E_(vii) E_(f) 4254 E_(1b)E₂E₃E_(ii)E₄ E_(vii) E_(f) 4255 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E_(vii) E_(f) 4256 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E_(vii) E_(f) 4257 E_(1a)E₂E_(iii) E_(vii) E_(f) 4258 E_(1b)E₂E_(iii) E_(vii) E_(f) 4259 E_(1a)E₂E₃E_(iii) E_(vii) E_(f) 4260 E_(1b)E₂E₃E_(iii) E_(vii) E_(f) 4261 E_(1a)E₂E_(iii)E₄ E_(vii) E_(f) 4262 E_(1b)E₂E_(iii)E₄ E_(vii) E_(f) 4263 E_(1a)E₂E₃E_(iii)E₄ E_(vii) E_(f) 4264 E_(1b)E₂E₃E_(iii)E₄ E_(vii) E_(f) 4265 E_(1a)E₂E_(iv) E_(vii) E_(f) 4266 E_(1b)E₂E_(iv) E_(vii) E_(f) 4267 E_(1a)E₂E₃E_(iv) E_(vii) E_(f) 4268 E_(1b)E₂E₃E_(iv) E_(vii) E_(f) 4269 E_(1a)E₂E_(iv)E₄ E_(vii) E_(f) 4270 E_(1b)E₂E_(iv)E₄ E_(vii) E_(f) 4271 E_(1a)E₂E₃E_(iv)E₄ E_(vii) E_(f) 4272 E_(1b)E₂E₃E_(iv)E₄ E_(vii) E_(f) 4273 E_(1a)E₂ E_(vii) E₄* E_(f) 4274 E_(1b)E₂ E_(vii) E₄* E_(f) 4275 E_(1a)E₂E₃ E_(vii) E₄* E_(f) 4276 E_(1b)E₂E₃ E_(vii) E₄* E_(f) 4277 E_(1a)E₂E_(i) E_(vii) E₄* E_(f) 4278 E_(1b)E₂E_(i) E_(vii) E₄* E_(f) 4279 E_(1a)E₂E_(ii) E_(vii) E₄* E_(f) 4280 E_(1b)E₂E_(ii) E_(vii) E₄* E_(f) 4281 E_(1a)E₂E_(ii)E_(iib) E_(vii) E₄* E_(f) 4282 E_(1b)E₂E_(ii)E_(iib) E_(vii) E₄* E_(f) 4283 E_(1a)E₂E₃E_(i) E_(vii) E₄* E_(f) 4284 E_(1b)E₂E₃E_(i) E_(vii) E₄* E_(f) 4285 E_(1a)E₂E₃E_(ii) E_(vii) E₄* E_(f) 4286 E_(1b)E₂E₃E_(ii) E_(vii) E₄* E_(f) 4287 E_(1a)E₂E₃E_(ii)E_(iib) E_(vii) E₄* E_(f) 4288 E_(1b)E₂E₃E_(ii)E_(iib) E_(vii) E₄* E_(f) 4289 E_(1a)E₂E₄ E_(vii) E₄* E_(f) 4290 E_(1b)E₂E₄ E_(vii) E₄* E_(f) 4291 E_(1a)E₂E₃E₄ E_(vii) E₄* E_(f) 4292 E_(1b)E₂E₃E₄ E_(vii) E₄* E_(f) 4293 E_(1a)E₂E_(i)E₄ E_(vii) E₄* E_(f) 4294 E_(1b)E₂E_(i)E₄ E_(vii) E₄* E_(f) 4295 E_(1a)E₂E_(ii)E₄ E_(vii) E₄* E_(f) 4296 E_(1b)E₂E_(ii)E₄ E_(vii) E₄* E_(f) 4297 E_(1a)E₂E_(ii)E_(iib)E₄ E_(vii) E₄* E_(f) 4298 E_(1b)E₂E_(ii)E_(iib)E₄ E_(vii) E₄* E_(f) 4299 E_(1a)E₂E₃E_(i)E₄ E_(vii) E₄* E_(f) 4300 E_(1b)E₂E₃E_(i)E₄ E_(vii) E₄* E_(f) 4301 E_(1a)E₂E₃E_(ii)E₄ E_(vii) E₄* E_(f) 4302 E_(1b)E₂E₃E_(ii)E₄ E_(vii) E₄* E_(f) 4303 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E_(vii) E₄* E_(f) 4304 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E_(vii) E₄* E_(f) 4305 E_(1a)E₂E_(iii) E_(vii) E₄* E_(f) 4306 E_(1b)E₂E_(iii) E_(vii) E₄* E_(f) 4307 E_(1a)E₂E₃E_(iii) E_(vii) E₄* E_(f) 4308 E_(1b)E₂E₃E_(iii) E_(vii) E₄* E_(f) 4309 E_(1a)E₂E_(iii)E₄ E_(vii) E₄* E_(f) 4310 E_(1b)E₂E_(iii)E₄ E_(vii) E₄* E_(f) 4311 E_(1a)E₂E₃E_(iii)E₄ E_(vii) E₄* E_(f) 4312 E_(1b)E₂E₃E_(iii)E₄ E_(vii) E₄* E_(f) 4313 E_(1a)E₂E_(iv) E_(vii) E₄* E_(f) 4314 E_(1b)E₂E_(iv) E_(vii) E₄* E_(f) 4315 E_(1a)E₂E₃E_(iv) E_(vii) E₄* E_(f) 4316 E_(1b)E₂E₃E_(iv) E_(vii) E₄* E_(f) 4317 E_(1a)E₂E_(iv)E₄ E_(vii) E₄* E_(f) 4318 E_(1b)E₂E_(iv)E₄ E_(vii) E₄* E_(f) 4319 E_(1a)E₂E₃E_(iv)E₄ E_(vii) E₄* E_(f) 4320 E_(1b)E₂E₃E_(iv)E₄ E_(vii) E₄* E_(f) 4321 E_(1a)E₂ E_(vii) E₅ E_(f) 4322 E_(1b)E₂ E_(vii) E₅ E_(f) 4323 E_(1a)E₂E₃ E_(vii) E₅ E_(f) 4324 E_(1b)E₂E₃ E_(vii) E₅ E_(f) 4325 E_(1a)E₂E_(i) E_(vii) E₅ E_(f) 4326 E_(1b)E₂E_(i) E_(vii) E₅ E_(f) 4327 E_(1a)E₂E_(ii) E_(vii) E₅ E_(f) 4328 E_(1b)E₂E_(ii) E_(vii) E₅ E_(f) 4329 E_(1a)E₂E_(ii)E_(iib) E_(vii) E₅ E_(f) 4330 E_(1b)E₂E_(ii)E_(iib) E_(vii) E₅ E_(f) 4331 E_(1a)E₂E₃E_(i) E_(vii) E₅ E_(f) 4332 E_(1b)E₂E₃E_(i) E_(vii) E₅ E_(f) 4333 E_(1a)E₂E₃E_(ii) E_(vii) E₅ E_(f) 4334 E_(1b)E₂E₃E_(ii) E_(vii) E₅ E_(f) 4335 E_(1a)E₂E₃E_(ii)E_(iib) E_(vii) E₅ E_(f) 4336 E_(1b)E₂E₃E_(ii)E_(iib) E_(vii) E₅ E_(f) 4337 E_(1a)E₂E₄ E_(vii) E₅ E_(f) 4338 E_(1b)E₂E₄ E_(vii) E₅ E_(f) 4339 E_(1a)E₂E₃E₄ E_(vii) E₅ E_(f) 4340 E_(1b)E₂E₃E₄ E_(vii) E₅ E_(f) 4341 E_(1a)E₂E_(i)E₄ E_(vii) E₅ E_(f) 4342 E_(1b)E₂E_(i)E₄ E_(vii) E₅ E_(f) 4343 E_(1a)E₂E_(ii)E₄ E_(vii) E₅ E_(f) 4344 E_(1b)E₂E_(ii)E₄ E_(vii) E₅ E_(f) 4345 E_(1a)E₂E_(ii)E_(iib)E₄ E_(vii) E₅ E_(f) 4346 E_(1b)E₂E_(ii)E_(iib)E₄ E_(vii) E₅ E_(f) 4347 E_(1a)E₂E₃E_(i)E₄ E_(vii) E₅ E_(f) 4348 E_(1b)E₂E₃E_(i)E₄ E_(vii) E₅ E_(f) 4349 E_(1a)E₂E₃E_(ii)E₄ E_(vii) E₅ E_(f) 4350 E_(1b)E₂E₃E_(ii)E₄ E_(vii) E₅ E_(f) 4351 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E_(vii) E₅ E_(f) 4352 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E_(vii) E₅ E_(f) 4353 E_(1a)E₂E_(iii) E_(vii) E₅ E_(f) 4354 E_(1b)E₂E_(iii) E_(vii) E₅ E_(f) 4355 E_(1a)E₂E₃E_(iii) E_(vii) E₅ E_(f) 4356 E_(1b)E₂E₃E_(iii) E_(vii) E₅ E_(f) 4357 E_(1a)E₂E_(iii)E₄ E_(vii) E₅ E_(f) 4358 E_(1b)E₂E_(iii)E₄ E_(vii) E₅ E_(f) 4359 E_(1a)E₂E₃E_(iii)E₄ E_(vii) E₅ E_(f) 4360 E_(1b)E₂E₃E_(iii)E₄ E_(vii) E₅ E_(f) 4361 E_(1a)E₂E_(iv) E_(vii) E₅ E_(f) 4362 E_(1b)E₂E_(iv) E_(vii) E₅ E_(f) 4363 E_(1a)E₂E₃E_(iv) E_(vii) E₅ E_(f) 4364 E_(1b)E₂E₃E_(iv) E_(vii) E₅ E_(f) 4365 E_(1a)E₂E_(iv)E₄ E_(vii) E₅ E_(f) 4366 E_(1b)E₂E_(iv)E₄ E_(vii) E₅ E_(f) 4367 E_(1a)E₂E₃E_(iv)E₄ E_(vii) E₅ E_(f) 4368 E_(1b)E₂E₃E_(iv)E₄ E_(vii) E₅ E_(f) 4369 E_(1a)E₂ E_(vii) E₄*E₅ E_(f) 4370 E_(1b)E₂ E_(vii) E₄*E₅ E_(f) 4371 E_(1a)E₂E₃ E_(vii) E₄*E₅ E_(f) 4372 E_(1b)E₂E₃ E_(vii) E₄*E₅ E_(f) 4373 E_(1a)E₂E_(i) E_(vii) E₄*E₅ E_(f) 4374 E_(1b)E₂E_(i) E_(vii) E₄*E₅ E_(f) 4375 E_(1a)E₂E_(ii) E_(vii) E₄*E₅ E_(f) 4376 E_(1b)E₂E_(ii) E_(vii) E₄*E₅ E_(f) 4377 E_(1a)E₂E_(ii)E_(iib) E_(vii) E₄*E₅ E_(f) 4378 E_(1b)E₂E_(ii)E_(iib) E_(vii) E₄*E₅ E_(f) 4379 E_(1a)E₂E₃E_(i) E_(vii) E₄*E₅ E_(f) 4380 E_(1b)E₂E₃E_(i) E_(vii) E₄*E₅ E_(f) 4381 E_(1a)E₂E₃E_(ii) E_(vii) E₄*E₅ E_(f) 4382 E_(1b)E₂E₃E_(ii) E_(vii) E₄*E₅ E_(f) 4383 E_(1a)E₂E₃E_(ii)E_(iib) E_(vii) E₄*E₅ E_(f) 4384 E_(1b)E₂E₃E_(ii)E_(iib) E_(vii) E₄*E₅ E_(f) 4385 E_(1a)E₂E₄ E_(vii) E₄*E₅ E_(f) 4386 E_(1b)E₂E₄ E_(vii) E₄*E₅ E_(f) 4387 E_(1a)E₂E₃E₄ E_(vii) E₄*E₅ E_(f) 4388 E_(1b)E₂E₃E₄ E_(vii) E₄*E₅ E_(f) 4389 E_(1a)E₂E_(i)E₄ E_(vii) E₄*E₅ E_(f) 4390 E_(1b)E₂E_(i)E₄ E_(vii) E₄*E₅ E_(f) 4391 E_(1a)E₂E_(ii)E₄ E_(vii) E₄*E₅ E_(f) 4392 E_(1b)E₂E_(ii)E₄ E_(vii) E₄*E₅ E_(f) 4393 E_(1a)E₂E_(ii)E_(iib)E₄ E_(vii) E₄*E₅ E_(f) 4394 E_(1b)E₂E_(ii)E_(iib)E₄ E_(vii) E₄*E₅ E_(f) 4395 E_(1a)E₂E₃E_(i)E₄ E_(vii) E₄*E₅ E_(f) 4396 E_(1b)E₂E₃E_(i)E₄ E_(vii) E₄*E₅ E_(f) 4397 E_(1a)E₂E₃E_(ii)E₄ E_(vii) E₄*E₅ E_(f) 4398 E_(1b)E₂E₃E_(ii)E₄ E_(vii) E₄*E₅ E_(f) 4399 E_(1a)E₂E₃E_(ii)E_(iib)E₄ E_(vii) E₄*E₅ E_(f) 4400 E_(1b)E₂E₃E_(ii)E_(iib)E₄ E_(vii) E₄*E₅ E_(f) 4401 E_(1a)E₂E_(iii) E_(vii) E₄*E₅ E_(f) 4402 E_(1b)E₂E_(iii) E_(vii) E₄*E₅ E_(f) 4403 E_(1a)E₂E₃E_(iii) E_(vii) E₄*E₅ E_(f) 4404 E_(1b)E₂E₃E_(iii) E_(vii) E₄*E₅ E_(f) 4405 E_(1a)E₂E_(iii)E₄ E_(vii) E₄*E₅ E_(f) 4406 E_(1b)E₂E_(iii)E₄ E_(vii) E₄*E₅ E_(f) 4407 E_(1a)E₂E₃E_(iii)E₄ E_(vii) E₄*E₅ E_(f) 4408 E_(1b)E₂E₃E_(iii)E₄ E_(vii) E₄*E₅ E_(f) 4409 E_(1a)E₂E_(iv) E_(vii) E₄*E₅ E_(f) 4410 E_(1b)E₂E_(iv) E_(vii) E₄*E₅ E_(f) 4411 E_(1a)E₂E₃E_(iv) E_(vii) E₄*E₅ E_(f) 4412 E_(1b)E₂E₃E_(iv) E_(vii) E₄*E₅ E_(f) 4413 E_(1a)E₂E_(iv)E₄ E_(vii) E₄*E₅ E_(f) 4414 E_(1b)E₂E_(iv)E₄ E_(vii) E₄*E₅ E_(f) 4415 E_(1a)E₂E₃E_(iv)E₄ E_(vii) E₄*E₅ E_(f) 4416 E_(1b)E₂E₃E_(iv)E₄ E_(vii) E₄*E₅ E_(f) 4417 E_(1a)E₂ AlkLE_(vii) E_(f) 4418 E_(1b)E₂ AlkLE_(vii) E_(f) 4419 E_(1a)E₂E₃ AlkLE_(vii) E_(f) 4420 E_(1b)E₂E₃ AlkLE_(vii) E_(f) 4421 E_(1a)E₂E_(i) AlkLE_(vii) E_(f) 4422 E_(1b)E₂E_(i) AlkLE_(vii) E_(f) 4423 E_(1a)E₂E_(ii) AlkLE_(vii) E_(f) 4424 E_(1b)E₂E_(ii) AlkLE_(vii) E_(f) 4425 E_(1a)E₂E_(ii)E_(iib) AlkLE_(vii) E_(f) 4426 E_(1b)E₂E_(ii)E_(iib) AlkLE_(vii) E_(f) 4427 E_(1a)E₂E₃E_(i) AlkLE_(vii) E_(f) 4428 E_(1b)E₂E₃E_(i) AlkLE_(vii) E_(f) 4429 E_(1a)E₂E₃E_(ii) AlkLE_(vii) E_(f) 4430 E_(1b)E₂E₃E_(ii) AlkLE_(vii) E_(f) 4431 E_(1a)E₂E₃E_(ii)E_(iib) AlkLE_(vii) E_(f) 4432 E_(1b)E₂E₃E_(ii)E_(iib) AlkLE_(vii) E_(f) 4433 E_(1a)E₂E₄ AlkLE_(vii) E_(f) 4434 E_(1b)E₂E₄ AlkLE_(vii) E_(f) 4435 E_(1a)E₂E₃E₄ AlkLE_(vii) E_(f) 4436 E_(1b)E₂E₃E₄ AlkLE_(vii) E_(f) 4437 E_(1a)E₂E_(i)E₄ AlkLE_(vii) E_(f) 4438 E_(1b)E₂E_(i)E₄ AlkLE_(vii) E_(f) 4439 E_(1a)E₂E_(ii)E₄ AlkLE_(vii) E_(f) 4440 E_(1b)E₂E_(ii)E₄ AlkLE_(vii) E_(f) 4441 E_(1a)E₂E_(ii)E_(iib)E₄ AlkLE_(vii) E_(f) 4442 E_(1b)E₂E_(ii)E_(iib)E₄ AlkLE_(vii) E_(f) 4443 E_(1a)E₂E₃E_(i)E₄ AlkLE_(vii) E_(f) 4444 E_(1b)E₂E₃E_(i)E₄ AlkLE_(vii) E_(f) 4445 E_(1a)E₂E₃E_(ii)E₄ AlkLE_(vii) E_(f) 4446 E_(1b)E₂E₃E_(ii)E₄ AlkLE_(vii) E_(f) 4447 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(vii) E_(f) 4448 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(vii) E_(f) 4449 E_(1a)E₂E_(iii) AlkLE_(vii) E_(f) 4450 E_(1b)E₂E_(iii) AlkLE_(vii) E_(f) 4451 E_(1a)E₂E₃E_(iii) AlkLE_(vii) E_(f) 4452 E_(1b)E₂E₃E_(iii) AlkLE_(vii) E_(f) 4453 E_(1a)E₂E_(iii)E₄ AlkLE_(vii) E_(f) 4454 E_(1b)E₂E_(iii)E₄ AlkLE_(vii) E_(f) 4455 E_(1a)E₂E₃E_(iii)E₄ AlkLE_(vii) E_(f) 4456 E_(1b)E₂E₃E_(iii)E₄ AlkLE_(vii) E_(f) 4457 E_(1a)E₂E_(iv) AlkLE_(vii) E_(f) 4458 E_(1b)E₂E_(iv) AlkLE_(vii) E_(f) 4459 E_(1a)E₂E₃E_(iv) AlkLE_(vii) E_(f) 4460 E_(1b)E₂E₃E_(iv) AlkLE_(vii) E_(f) 4461 E_(1a)E₂E_(iv)E₄ AlkLE_(vii) E_(f) 4462 E_(1b)E₂E_(iv)E₄ AlkLE_(vii) E_(f) 4463 E_(1a)E₂E₃E_(iv)E₄ AlkLE_(vii) E_(f) 4464 E_(1b)E₂E₃E_(iv)E₄ AlkLE_(vii) E_(f) 4465 E_(1a)E₂ AlkLE_(vii) E₄* E_(f) 4466 E_(1b)E₂ AlkLE_(vii) E₄* E_(f) 4467 E_(1a)E₂E₃ AlkLE_(vii) E₄* E_(f) 4468 E_(1b)E₂E₃ AlkLE_(vii) E₄* E_(f) 4469 E_(1a)E₂E_(i) AlkLE_(vii) E₄* E_(f) 4470 E_(1b)E₂E_(i) AlkLE_(vii) E₄* E_(f) 4471 E_(1a)E₂E_(ii) AlkLE_(vii) E₄* E_(f) 4472 E_(1b)E₂E_(ii) AlkLE_(vii) E₄* E_(f) 4473 E_(1a)E₂E_(ii)E_(iib) AlkLE_(vii) E₄* E_(f) 4474 E_(1b)E₂E_(ii)E_(iib) AlkLE_(vii) E₄* E_(f) 4475 E_(1a)E₂E₃E_(i) AlkLE_(vii) E₄* E_(f) 4476 E_(1b)E₂E₃E_(i) AlkLE_(vii) E₄* E_(f) 4477 E_(1a)E₂E₃E_(ii) AlkLE_(vii) E₄* E_(f) 4478 E_(1b)E₂E₃E_(ii) AlkLE_(vii) E₄* E_(f) 4479 E_(1a)E₂E₃E_(ii)E_(iib) AlkLE_(vii) E₄* E_(f) 4480 E_(1b)E₂E₃E_(ii)E_(iib) AlkLE_(vii) E₄* E_(f) 4481 E_(1a)E₂E₄ AlkLE_(vii) E₄* E_(f) 4482 E_(1b)E₂E₄ AlkLE_(vii) E₄* E_(f) 4483 E_(1a)E₂E₃E₄ AlkLE_(vii) E₄* E_(f) 4484 E_(1b)E₂E₃E₄ AlkLE_(vii) E₄* E_(f) 4485 E_(1a)E₂E_(i)E₄ AlkLE_(vii) E₄* E_(f) 4486 E_(1b)E₂E_(i)E₄ AlkLE_(vii) E₄* E_(f) 4487 E_(1a)E₂E_(ii)E₄ AlkLE_(vii) E₄* E_(f) 4488 E_(1b)E₂E_(ii)E₄ AlkLE_(vii) E₄* E_(f) 4489 E_(1a)E₂E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* E_(f) 4490 E_(1b)E₂E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* E_(f) 4491 E_(1a)E₂E₃E_(i)E₄ AlkLE_(vii) E₄* E_(f) 4492 E_(1b)E₂E₃E_(i)E₄ AlkLE_(vii) E₄* E_(f) 4493 E_(1a)E₂E₃E_(ii)E₄ AlkLE_(vii) E₄* E_(f) 4494 E_(1b)E₂E₃E_(ii)E₄ AlkLE_(vii) E₄* E_(f) 4495 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* E_(f) 4496 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* E_(f) 4497 E_(1a)E₂E_(iii) AlkLE_(vii) E₄* E_(f) 4498 E_(1b)E₂E_(iii) AlkLE_(vii) E₄* E_(f) 4499 E_(1a)E₂E₃E_(iii) AlkLE_(vii) E₄* E_(f) 4500 E_(1b)E₂E₃E_(iii) AlkLE_(vii) E₄* E_(f) 4501 E_(1a)E₂E_(iii)E₄ AlkLE_(vii) E₄* E_(f) 4502 E_(1b)E₂E_(iii)E₄ AlkLE_(vii) E₄* E_(f) 4503 E_(1a)E₂E₃E_(iii)E₄ AlkLE_(vii) E₄* E_(f) 4504 E_(1b)E₂E₃E_(iii)E₄ AlkLE_(vii) E₄* E_(f) 4505 E_(1a)E₂E_(iv) AlkLE_(vii) E₄* E_(f) 4506 E_(1b)E₂E_(iv) AlkLE_(vii) E₄* E_(f) 4507 E_(1a)E₂E₃E_(iv) AlkLE_(vii) E₄* E_(f) 4508 E_(1b)E₂E₃E_(iv) AlkLE_(vii) E₄* E_(f) 4509 E_(1a)E₂E_(iv)E₄ AlkLE_(vii) E₄* E_(f) 4510 E_(1b)E₂E_(iv)E₄ AlkLE_(vii) E₄* E_(f) 4511 E_(1a)E₂E₃E_(iv)E₄ AlkLE_(vii) E₄* E_(f) 4512 E_(1b)E₂E₃E_(iv)E₄ AlkLE_(vii) E₄* E_(f) 4513 E_(1a)E₂ AlkLE_(vii) E₅ E_(f) 4514 E_(1b)E₂ AlkLE_(vii) E₅ E_(f) 4515 E_(1a)E₂E₃ AlkLE_(vii) E₅ E_(f) 4516 E_(1b)E₂E₃ AlkLE_(vii) E₅ E_(f) 4517 E_(1a)E₂E_(i) AlkLE_(vii) E₅ E_(f) 4518 E_(1b)E₂E_(i) AlkLE_(vii) E₅ E_(f) 4519 E_(1a)E₂E_(ii) AlkLE_(vii) E₅ E_(f) 4520 E_(1b)E₂E_(ii) AlkLE_(vii) E₅ E_(f) 4521 E_(1a)E₂E_(ii)E_(iib) AlkLE_(vii) E₅ E_(f) 4522 E_(1b)E₂E_(ii)E_(iib) AlkLE_(vii) E₅ E_(f) 4523 E_(1a)E₂E₃E_(i) AlkLE_(vii) E₅ E_(f) 4524 E_(1b)E₂E₃E_(i) AlkLE_(vii) E₅ E_(f) 4525 E_(1a)E₂E₃E_(ii) AlkLE_(vii) E₅ E_(f) 4526 E_(1b)E₂E₃E_(ii) AlkLE_(vii) E₅ E_(f) 4527 E_(1a)E₂E₃E_(ii)E_(iib) AlkLE_(vii) E₅ E_(f) 4528 E_(1b)E₂E₃E_(ii)E_(iib) AlkLE_(vii) E₅ E_(f) 4529 E_(1a)E₂E₄ AlkLE_(vii) E₅ E_(f) 4530 E_(1b)E₂E₄ AlkLE_(vii) E₅ E_(f) 4531 E_(1a)E₂E₃E₄ AlkLE_(vii) E₅ E_(f) 4532 E_(1b)E₂E₃E₄ AlkLE_(vii) E₅ E_(f) 4533 E_(1a)E₂E_(i)E₄ AlkLE_(vii) E₅ E_(f) 4534 E_(1b)E₂E_(i)E₄ AlkLE_(vii) E₅ E_(f) 4535 E_(1a)E₂E_(ii)E₄ AlkLE_(vii) E₅ E_(f) 4536 E_(1b)E₂E_(ii)E₄ AlkLE_(vii) E₅ E_(f) 4537 E_(1a)E₂E_(ii)E_(iib)E₄ AlkLE_(vii) E₅ E_(f) 4538 E_(1b)E₂E_(ii)E_(iib)E₄ AlkLE_(vii) E₅ E_(f) 4539 E_(1a)E₂E₃E_(i)E₄ AlkLE_(vii) E₅ E_(f) 4540 E_(1b)E₂E₃E_(i)E₄ AlkLE_(vii) E₅ E_(f) 4541 E_(1a)E₂E₃E_(ii)E₄ AlkLE_(vii) E₅ E_(f) 4542 E_(1b)E₂E₃E_(ii)E₄ AlkLE_(vii) E₅ E_(f) 4543 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(vii) E₅ E_(f) 4544 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(vii) E₅ E_(f) 4545 E_(1a)E₂E_(iii) AlkLE_(vii) E₅ E_(f) 4546 E_(1b)E₂E_(iii) AlkLE_(vii) E₅ E_(f) 4547 E_(1a)E₂E₃E_(iii) AlkLE_(vii) E₅ E_(f) 4548 E_(1b)E₂E₃E_(iii) AlkLE_(vii) E₅ E_(f) 4549 E_(1a)E₂E_(iii)E₄ AlkLE_(vii) E₅ E_(f) 4550 E_(1b)E₂E_(iii)E₄ AlkLE_(vii) E₅ E_(f) 4551 E_(1a)E₂E₃E_(iii)E₄ AlkLE_(vii) E₅ E_(f) 4552 E_(1b)E₂E₃E_(iii)E₄ AlkLE_(vii) E₅ E_(f) 4553 E_(1a)E₂E_(iv) AlkLE_(vii) E₅ E_(f) 4554 E_(1b)E₂E_(iv) AlkLE_(vii) E₅ E_(f) 4555 E_(1a)E₂E₃E_(iv) AlkLE_(vii) E₅ E_(f) 4556 E_(1b)E₂E₃E_(iv) AlkLE_(vii) E₅ E_(f) 4557 E_(1a)E₂E_(iv)E₄ AlkLE_(vii) E₅ E_(f) 4558 E_(1b)E₂E_(iv)E₄ AlkLE_(vii) E₅ E_(f) 4559 E_(1a)E₂E₃E_(iv)E₄ AlkLE_(vii) E₅ E_(f) 4560 E_(1b)E₂E₃E_(iv)E₄ AlkLE_(vii) E₅ E_(f) 4561 E_(1a)E₂ AlkLE_(vii) E₄*E₅ E_(f) 4562 E_(1b)E₂ AlkLE_(vii) E₄*E₅ E_(f) 4563 E_(1a)E₂E₃ AlkLE_(vii) E₄*E₅ E_(f) 4564 E_(1b)E₂E₃ AlkLE_(vii) E₄*E₅ E_(f) 4565 E_(1a)E₂E_(i) AlkLE_(vii) E₄*E₅ E_(f) 4566 E_(1b)E₂E_(i) AlkLE_(vii) E₄*E₅ E_(f) 4567 E_(1a)E₂E_(ii) AlkLE_(vii) E₄*E₅ E_(f) 4568 E_(1b)E₂E_(ii) AlkLE_(vii) E₄*E₅ E_(f) 4569 E_(1a)E₂E_(ii)E_(iib) AlkLE_(vii) E₄*E₅ E_(f) 4570 E_(1b)E₂E_(ii)E_(iib) AlkLE_(vii) E₄*E₅ E_(f) 4571 E_(1a)E₂E₃E_(i) AlkLE_(vii) E₄*E₅ E_(f) 4572 E_(1b)E₂E₃E_(i) AlkLE_(vii) E₄*E₅ E_(f) 4573 E_(1a)E₂E₃E_(ii) AlkLE_(vii) E₄*E₅ E_(f) 4574 E_(1b)E₂E₃E_(ii) AlkLE_(vii) E₄*E₅ E_(f) 4575 E_(1a)E₂E₃E_(ii)E_(iib) AlkLE_(vii) E₄*E₅ E_(f) 4576 E_(1b)E₂E₃E_(ii)E_(iib) AlkLE_(vii) E₄*E₅ E_(f) 4577 E_(1a)E₂E₄ AlkLE_(vii) E₄*E₅ E_(f) 4578 E_(1b)E₂E₄ AlkLE_(vii) E₄*E₅ E_(f) 4579 E_(1a)E₂E₃E₄ AlkLE_(vii) E₄*E₅ E_(f) 4580 E_(1b)E₂E₃E₄ AlkLE_(vii) E₄*E₅ E_(f) 4581 E_(1a)E₂E_(i)E₄ AlkLE_(vii) E₄*E₅ E_(f) 4582 E_(1b)E₂E_(i)E₄ AlkLE_(vii) E₄*E₅ E_(f) 4583 E_(1a)E₂E_(ii)E₄ AlkLE_(vii) E₄*E₅ E_(f) 4584 E_(1b)E₂E_(ii)E₄ AlkLE_(vii) E₄*E₅ E_(f) 4585 E_(1a)E₂E_(ii)E_(iib)E₄ AlkLE_(vii) E₄*E₅ E_(f) 4586 E_(1b)E₂E_(ii)E_(iib)E₄ AlkLE_(vii) E₄*E₅ E_(f) 4587 E_(1a)E₂E₃E_(i)E₄ AlkLE_(vii) E₄*E₅ E_(f) 4588 E_(1b)E₂E₃E_(i)E₄ AlkLE_(vii) E₄*E₅ E_(f) 4589 E_(1a)E₂E₃E_(ii)E₄ AlkLE_(vii) E₄*E₅ E_(f) 4590 E_(1b)E₂E₃E_(ii)E₄ AlkLE_(vii) E₄*E₅ E_(f) 4591 E_(1a)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(vii) E₄*E₅ E_(f) 4592 E_(1b)E₂E₃E_(ii)E_(iib)E₄ AlkLE_(vii) E₄*E₅ E_(f) 4593 E_(1a)E₂E_(iii) AlkLE_(vii) E₄*E₅ E_(f) 4594 E_(1b)E₂E_(iii) AlkLE_(vii) E₄*E₅ E_(f) 4595 E_(1a)E₂E₃E_(iii) AlkLE_(vii) E₄*E₅ E_(f) 4596 E_(1b)E₂E₃E_(iii) AlkLE_(vii) E₄*E₅ E_(f) 4597 E_(1a)E₂E_(iii)E₄ AlkLE_(vii) E₄*E₅ E_(f) 4598 E_(1b)E₂E_(iii)E₄ AlkLE_(vii) E₄*E₅ E_(f) 4599 E_(1a)E₂E₃E_(iii)E₄ AlkLE_(vii) E₄*E₅ E_(f) 4600 E_(1b)E₂E₃E_(iii)E₄ AlkLE_(vii) E₄*E₅ E_(f) 4601 E_(1a)E₂E_(iv) AlkLE_(vii) E₄*E₅ E_(f) 4602 E_(1b)E₂E_(iv) AlkLE_(vii) E₄*E₅ E_(f) 4603 E_(1a)E₂E₃E_(iv) AlkLE_(vii) E₄*E₅ E_(f) 4604 E_(1b)E₂E₃E_(iv) AlkLE_(vii) E₄*E₅ E_(f) 4605 E_(1a)E₂E_(iv)E₄ AlkLE_(vii) E₄*E₅ E_(f) 4606 E_(1b)E₂E_(iv)E₄ AlkLE_(vii) E₄*E₅ E_(f) 4607 E_(1a)E₂E₃E_(iv)E₄ AlkLE_(vii) E₄*E₅ E_(f) 4608 E_(1b)E₂E₃E_(iv)E₄ AlkLE_(vii) E₄*E₅ E_(f)

Microorganisms quite especially preferred according to the invention (abbreviated as MO) are outstandingly suitable for the production of ω-hydroxycarboxylic acids or ω-oxocarboxylic acids and have increased or decreased enzyme activities (abbreviated as E) described in the following table, where these can in addition advantageously be combined with an increased enzyme activity compared to the wild type of the microorganism, which is described for the 3-ketoacyl-ACP (Acyl Carrrier Protein) synthase III (EC 2.3.1.41), in particular that from plants, preferably that from plants the seeds whereof contain fatty acids with alkyl residues shorter than 14 C atoms, and particularly preferably that from plants of the genera Cuphea, Elaeis, Cocos, Umbellularia and Cinnamomum and gene products selected from AccA, AccB, AccC, AccD, AceE, AceF, Lpd, AcpP, FabA, FabB, FabD, FabF, FabG, FabH, Fabl, FabZ, PanD, PanK, UdhA, PntA or PntB.

Any combinations of at least two of these enzyme activities can advantageously be increased.

In addition, moreover, it can be advantageous if the microorganism is provided with a lower enzyme activity compared to the wild type of the microorganism, which is described for the gene products selected from TdcE, PflA, PflB, PflC, PflD, PoxB, YgfG, AckA, AckB, TdcD, Pta, LdhA, AdhE, MgsA, FdnG, FdnH, FdnI, FdhF, FdoG, FdoH, FdoI, PrpC, PrpD, PrpF, PrpB, TdcD, Pdc, PorA, PorB, PorC, PorD, AlsS, IlvB, IlvM, IlvN, IlvG, IlvI, IlvH, AlsD, ButB, Thl, ThlA, ThlB, PhaA, PhaB, Crt, BdhA, BdhB, Adc, Adh, CtfB, AtoA, AtoD, LdhL, GltA, FabR, FhuA, Dld, LldA or LldP, singly or in any combination.

MO E increased E decreased 1 E_(1a) 2 E_(1b) 3 E_(1a)E_(i) 4 E_(1b)E_(i) 5 E_(1a)E_(ii) 6 E_(1b)E_(ii) 7 E_(1a)E_(ii)E_(iib) 8 E_(1b)E_(ii)E_(iib) 9 E_(1a)E₄ 10 E_(1b)E₄ 11 E_(1a)E_(i)E₄ 12 E_(1b)E_(i)E₄ 13 E_(1a)E_(ii)E₄ 14 E_(1b)E_(ii)E₄ 15 E_(1a)E_(ii)E_(iib)E₄ 16 E_(1b)E_(ii)E_(iib)E₄ 17 E_(1a)E_(iii) 18 E_(1b)E_(iii) 19 E_(1a)E_(iii)E₄ 20 E_(1b)E_(iii)E₄ 21 E_(1a)E_(iv) 22 E_(1b)E_(iv) 23 E_(1a)E_(iv)E₄ 24 E_(1b)E_(iv)E₄ 25 E_(1a) E₄* 26 E_(1b) E₄* 27 E_(1a)E_(i) E₄* 28 E_(1b)E_(i) E₄* 29 E_(1a)E_(ii) E₄* 30 E_(1b)E_(ii) E₄* 31 E_(1a)E_(ii)E_(iib) E₄* 32 E_(1b)E_(ii)E_(iib) E₄* 33 E_(1a)E₄ E₄* 34 E_(1b)E₄ E₄* 35 E_(1a)E_(i)E₄ E₄* 36 E_(1b)E_(i)E₄ E₄* 37 E_(1a)E_(ii)E₄ E₄* 38 E_(1b)E_(ii)E₄ E₄* 39 E_(1a)E_(ii)E_(iib)E₄ E₄* 40 E_(1b)E_(ii)E_(iib)E₄ E₄* 41 E_(1a)E_(iii) E₄* 42 E_(1b)E_(iii) E₄* 43 E_(1a)E_(iii)E₄ E₄* 44 E_(1b)E_(iii)E₄ E₄* 45 E_(1a)E_(iv) E₄* 46 E_(1b)E_(iv) E₄* 47 E_(1a)E_(iv)E₄ E₄* 48 E_(1b)E_(iv)E₄ E₄* 49 E_(1a) E₅ 50 E_(1b) E₅ 51 E_(1a)E_(i) E₅ 52 E_(1b)E_(i) E₅ 53 E_(1a)E_(ii) E₅ 54 E_(1b)E_(ii) E₅ 55 E_(1a)E_(ii)E_(iib) E₅ 56 E_(1b)E_(ii)E_(iib) E₅ 57 E_(1a)E₄ E₅ 58 E_(1b)E₄ E₅ 59 E_(1a)E_(i)E₄ E₅ 60 E_(1b)E_(i)E₄ E₅ 61 E_(1a)E_(ii)E₄ E₅ 62 E_(1b)E_(ii)E₄ E₅ 63 E_(1a)E_(ii)E_(iib)E₄ E₅ 64 E_(1b)E_(ii)E_(iib)E₄ E₅ 65 E_(1a)E_(iii) E₅ 66 E_(1b)E_(iii) E₅ 67 E_(1a)E_(iii)E₄ E₅ 68 E_(1b)E_(iii)E₄ E₅ 69 E_(1a)E_(iv) E₅ 70 E_(1b)E_(iv) E₅ 71 E_(1a)E_(iv)E₄ E₅ 72 E_(1b)E_(iv)E₄ E₅ 73 E_(1a) E₄*E₅ 74 E_(1b) E₄*E₅ 75 E_(1a)E_(i) E₄*E₅ 76 E_(1b)E_(i) E₄*E₅ 77 E_(1a)E_(ii) E₄*E₅ 78 E_(1b)E_(ii) E₄*E₅ 79 E_(1a)E_(ii)E_(iib) E₄*E₅ 80 E_(1b)E_(ii)E_(iib) E₄*E₅ 81 E_(1a)E₄ E₄*E₅ 82 E_(1b)E₄ E₄*E₅ 83 E_(1a)E_(i)E₄ E₄*E₅ 84 E_(1b)E_(i)E₄ E₄*E₅ 85 E_(1a)E_(ii)E₄ E₄*E₅ 86 E_(1b)E_(ii)E₄ E₄*E₅ 87 E_(1a)E_(ii)E_(iib)E₄ E₄*E₅ 88 E_(1b)E_(ii)E_(iib)E₄ E₄*E₅ 89 E_(1a)E_(iii) E₄*E₅ 90 E_(1b)E_(iii) E₄*E₅ 91 E_(1a)E_(iii)E₄ E₄*E₅ 92 E_(1b)E_(iii)E₄ E₄*E₅ 93 E_(1a)E_(iv) E₄*E₅ 94 E_(1b)E_(iv) E₄*E₅ 95 E_(1a)E_(iv)E₄ E₄*E₅ 96 E_(1b)E_(iv)E₄ E₄*E₅ 97 E_(1a) AlkL 98 E_(1b) AlkL 99 E_(1a)E_(i) AlkL 100 E_(1b)E_(i) AlkL 101 E_(1a)E_(ii) AlkL 102 E_(1b)E_(ii) AlkL 103 E_(1a)E_(ii)E_(iib) AlkL 104 E_(1b)E_(ii)E_(iib) AlkL 105 E_(1a)E₄ AlkL 106 E_(1b)E₄ AlkL 107 E_(1a)E_(i)E₄ AlkL 108 E_(1b)E_(i)E₄ AlkL 109 E_(1a)E_(ii)E₄ AlkL 110 E_(1b)E_(ii)E₄ AlkL 111 E_(1a)E_(ii)E_(iib)E₄ AlkL 112 E_(1b)E_(ii)E_(iib)E₄ AlkL 113 E_(1a)E_(iii) AlkL 114 E_(1b)E_(iii) AlkL 115 E_(1a)E_(iii)E₄ AlkL 116 E_(1b)E_(iii)E₄ AlkL 117 E_(1a)E_(iv) AlkL 118 E_(1b)E_(iv) AlkL 119 E_(1a)E_(iv)E₄ AlkL 120 E_(1b)E_(iv)E₄ AlkL 121 E_(1a) AlkL E₄* 122 E_(1b) AlkL E₄* 123 E_(1a)E_(i) AlkL E₄* 124 E_(1b)E_(i) AlkL E₄* 125 E_(1a)E_(ii) AlkL E₄* 126 E_(1b)E_(ii) AlkL E₄* 127 E_(1a)E_(ii)E_(iib) AlkL E₄* 128 E_(1b)E_(ii)E_(iib) AlkL E₄* 129 E_(1a)E₄ AlkL E₄* 130 E_(1b)E₄ AlkL E₄* 131 E_(1a)E_(i)E₄ AlkL E₄* 132 E_(1b)E_(i)E₄ AlkL E₄* 133 E_(1a)E_(ii)E₄ AlkL E₄* 134 E_(1b)E_(ii)E₄ AlkL E₄* 135 E_(1a)E_(ii)E_(iib)E₄ AlkL E₄* 136 E_(1b)E_(ii)E_(iib)E₄ AlkL E₄* 137 E_(1a)E_(iii) AlkL E₄* 138 E_(1b)E_(iii) AlkL E₄* 139 E_(1a)E_(iii)E₄ AlkL E₄* 140 E_(1b)E_(iii)E₄ AlkL E₄* 141 E_(1a)E_(iv) AlkL E₄* 142 E_(1b)E_(iv) AlkL E₄* 143 E_(1a)E_(iv)E₄ AlkL E₄* 144 E_(1b)E_(iv)E₄ AlkL E₄* 145 E_(1a) AlkL E₅ 146 E_(1b) AlkL E₅ 147 E_(1a)E_(i) AlkL E₅ 148 E_(1b)E_(i) AlkL E₅ 149 E_(1a)E_(ii) AlkL E₅ 150 E_(1b)E_(ii) AlkL E₅ 151 E_(1a)E_(ii)E_(iib) AlkL E₅ 152 E_(1b)E_(ii)E_(iib) AlkL E₅ 153 E_(1a)E₄ AlkL E₅ 154 E_(1b)E₄ AlkL E₅ 155 E_(1a)E_(i)E₄ AlkL E₅ 156 E_(1b)E_(i)E₄ AlkL E₅ 157 E_(1a)E_(ii)E₄ AlkL E₅ 158 E_(1b)E_(ii)E₄ AlkL E₅ 159 E_(1a)E_(ii)E_(iib)E₄ AlkL E₅ 160 E_(1b)E_(ii)E_(iib)E₄ AlkL E₅ 161 E_(1a)E_(iii) AlkL E₅ 162 E_(1b)E_(iii) AlkL E₅ 163 E_(1a)E_(iii)E₄ AlkL E₅ 164 E_(1b)E_(iii)E₄ AlkL E₅ 165 E_(1a)E_(iv) AlkL E₅ 166 E_(1b)E_(iv) AlkL E₅ 167 E_(1a)E_(iv)E₄ AlkL E₅ 168 E_(1b)E_(iv)E₄ AlkL E₅ 169 E_(1a) AlkL E₄*E₅ 170 E_(1b) AlkL E₄*E₅ 171 E_(1a)E_(i) AlkL E₄*E₅ 172 E_(1b)E_(i) AlkL E₄*E₅ 173 E_(1a)E_(ii) AlkL E₄*E₅ 174 E_(1b)E_(ii) AlkL E₄*E₅ 175 E_(1a)E_(ii)E_(iib) AlkL E₄*E₅ 176 E_(1b)E_(ii)E_(iib) AlkL E₄*E₅ 177 E_(1a)E₄ AlkL E₄*E₅ 178 E_(1b)E₄ AlkL E₄*E₅ 179 E_(1a)E_(i)E₄ AlkL E₄*E₅ 180 E_(1b)E_(i)E₄ AlkL E₄*E₅ 181 E_(1a)E_(ii)E₄ AlkL E₄*E₅ 182 E_(1b)E_(ii)E₄ AlkL E₄*E₅ 183 E_(1a)E_(ii)E_(iib)E₄ AlkL E₄*E₅ 184 E_(1b)E_(ii)E_(iib)E₄ AlkL E₄*E₅ 185 E_(1a)E_(iii) AlkL E₄*E₅ 186 E_(1b)E_(iii) AlkL E₄*E₅ 187 E_(1a)E_(iii)E₄ AlkL E₄*E₅ 188 E_(1b)E_(iii)E₄ AlkL E₄*E₅ 189 E_(1a)E_(iv) AlkL E₄*E₅ 190 E_(1b)E_(iv) AlkL E₄*E₅ 191 E_(1a)E_(iv)E₄ AlkL E₄*E₅ 192 E_(1b)E_(iv)E₄ AlkL E₄*E₅ 193 E_(1a) E_(a) 194 E_(1b) E_(a) 195 E_(1a)E_(i) E_(a) 196 E_(1b)E_(i) E_(a) 197 E_(1a)E_(ii) E_(a) 198 E_(1b)E_(ii) E_(a) 199 E_(1a)E_(ii)E_(iib) E_(a) 200 E_(1b)E_(ii)E_(iib) E_(a) 201 E_(1a)E₄ E_(a) 202 E_(1b)E₄ E_(a) 203 E_(1a)E_(i)E₄ E_(a) 204 E_(1b)E_(i)E₄ E_(a) 205 E_(1a)E_(ii)E₄ E_(a) 206 E_(1b)E_(ii)E₄ E_(a) 207 E_(1a)E_(ii)E_(iib)E₄ E_(a) 208 E_(1b)E_(ii)E_(iib)E₄ E_(a) 209 E_(1a)E_(iii) E_(a) 210 E_(1b)E_(iii) E_(a) 211 E_(1a)E_(iii)E₄ E_(a) 212 E_(1b)E_(iii)E₄ E_(a) 213 E_(1a)E_(iv) E_(a) 214 E_(1b)E_(iv) E_(a) 215 E_(1a)E_(iv)E₄ E_(a) 216 E_(1b)E_(iv)E₄ E_(a) 217 E_(1a) E₄* E_(a) 218 E_(1b) E₄* E_(a) 219 E_(1a)E_(i) E₄* E_(a) 220 E_(1b)E_(i) E₄* E_(a) 221 E_(1a)E_(ii) E₄* E_(a) 222 E_(1b)E_(ii) E₄* E_(a) 223 E_(1a)E_(ii)E_(iib) E₄* E_(a) 224 E_(1b)E_(ii)E_(iib) E₄* E_(a) 225 E_(1a)E₄ E₄* E_(a) 226 E_(1b)E₄ E₄* E_(a) 227 E_(1a)E_(i)E₄ E₄* E_(a) 228 E_(1b)E_(i)E₄ E₄* E_(a) 229 E_(1a)E_(ii)E₄ E₄* E_(a) 230 E_(1b)E_(ii)E₄ E₄* E_(a) 231 E_(1a)E_(ii)E_(iib)E₄ E₄* E_(a) 232 E_(1b)E_(ii)E_(iib)E₄ E₄* E_(a) 233 E_(1a)E_(iii) E₄* E_(a) 234 E_(1b)E_(iii) E₄* E_(a) 235 E_(1a)E_(iii)E₄ E₄* E_(a) 236 E_(1b)E_(iii)E₄ E₄* E_(a) 237 E_(1a)E_(iv) E₄* E_(a) 238 E_(1b)E_(iv) E₄* E_(a) 239 E_(1a)E_(iv)E₄ E₄* E_(a) 240 E_(1b)E_(iv)E₄ E₄* E_(a) 241 E_(1a) E₅ E_(a) 242 E_(1b) E₅ E_(a) 243 E_(1a)E_(i) E₅ E_(a) 244 E_(1b)E_(i) E₅ E_(a) 245 E_(1a)E_(ii) E₅ E_(a) 246 E_(1b)E_(ii) E₅ E_(a) 247 E_(1a)E_(ii)E_(iib) E₅ E_(a) 248 E_(1b)E_(ii)E_(iib) E₅ E_(a) 249 E_(1a)E₄ E₅ E_(a) 250 E_(1b)E₄ E₅ E_(a) 251 E_(1a)E_(i)E₄ E₅ E_(a) 252 E_(1b)E_(i)E₄ E₅ E_(a) 253 E_(1a)E_(ii)E₄ E₅ E_(a) 254 E_(1b)E_(ii)E₄ E₅ E_(a) 255 E_(1a)E_(ii)E_(iib)E₄ E₅ E_(a) 256 E_(1b)E_(ii)E_(iib)E₄ E₅ E_(a) 257 E_(1a)E_(iii) E₅ E_(a) 258 E_(1b)E_(iii) E₅ E_(a) 259 E_(1a)E_(iii)E₄ E₅ E_(a) 260 E_(1b)E_(iii)E₄ E₅ E_(a) 261 E_(1a)E_(iv) E₅ E_(a) 262 E_(1b)E_(iv) E₅ E_(a) 263 E_(1a)E_(iv)E₄ E₅ E_(a) 264 E_(1b)E_(iv)E₄ E₅ E_(a) 265 E_(1a) E₄*E₅ E_(a) 266 E_(1b) E₄*E₅ E_(a) 267 E_(1a)E_(i) E₄*E₅ E_(a) 268 E_(1b)E_(i) E₄*E₅ E_(a) 269 E_(1a)E_(ii) E₄*E₅ E_(a) 270 E_(1b)E_(ii) E₄*E₅ E_(a) 271 E_(1a)E_(ii)E_(iib) E₄*E₅ E_(a) 272 E_(1b)E_(ii)E_(iib) E₄*E₅ E_(a) 273 E_(1a)E₄ E₄*E₅ E_(a) 274 E_(1b)E₄ E₄*E₅ E_(a) 275 E_(1a)E_(i)E₄ E₄*E₅ E_(a) 276 E_(1b)E_(i)E₄ E₄*E₅ E_(a) 277 E_(1a)E_(ii)E₄ E₄*E₅ E_(a) 278 E_(1b)E_(ii)E₄ E₄*E₅ E_(a) 279 E_(1a)E_(ii)E_(iib)E₄ E₄*E₅ E_(a) 280 E_(1b)E_(ii)E_(iib)E₄ E₄*E₅ E_(a) 281 E_(1a)E_(iii) E₄*E₅ E_(a) 282 E_(1b)E_(iii) E₄*E₅ E_(a) 283 E_(1a)E_(iii)E₄ E₄*E₅ E_(a) 284 E_(1b)E_(iii)E₄ E₄*E₅ E_(a) 285 E_(1a)E_(iv) E₄*E₅ E_(a) 286 E_(1b)E_(iv) E₄*E₅ E_(a) 287 E_(1a)E_(iv)E₄ E₄*E₅ E_(a) 288 E_(1b)E_(iv)E₄ E₄*E₅ E_(a) 289 E_(1a) AlkL E_(a) 290 E_(1b) AlkL E_(a) 291 E_(1a)E_(i) AlkL E_(a) 292 E_(1b)E_(i) AlkL E_(a) 293 E_(1a)E_(ii) AlkL E_(a) 294 E_(1b)E_(ii) AlkL E_(a) 295 E_(1a)E_(ii)E_(iib) AlkL E_(a) 296 E_(1b)E_(ii)E_(iib) AlkL E_(a) 297 E_(1a)E₄ AlkL E_(a) 298 E_(1b)E₄ AlkL E_(a) 299 E_(1a)E_(i)E₄ AlkL E_(a) 300 E_(1b)E_(i)E₄ AlkL E_(a) 301 E_(1a)E_(ii)E₄ AlkL E_(a) 302 E_(1b)E_(ii)E₄ AlkL E_(a) 303 E_(1a)E_(ii)E_(iib)E₄ AlkL E_(a) 304 E_(1b)E_(ii)E_(iib)E₄ AlkL E_(a) 305 E_(1a)E_(iii) AlkL E_(a) 306 E_(1b)E_(iii) AlkL E_(a) 307 E_(1a)E_(iii)E₄ AlkL E_(a) 308 E_(1b)E_(iii)E₄ AlkL E_(a) 309 E_(1a)E_(iv) AlkL E_(a) 310 E_(1b)E_(iv) AlkL E_(a) 311 E_(1a)E_(iv)E₄ AlkL E_(a) 312 E_(1b)E_(iv)E₄ AlkL E_(a) 313 E_(1a) AlkL E₄* E_(a) 314 E_(1b) AlkL E₄* E_(a) 315 E_(1a)E_(i) AlkL E₄* E_(a) 316 E_(1b)E_(i) AlkL E₄* E_(a) 317 E_(1a)E_(ii) AlkL E₄* E_(a) 318 E_(1b)E_(ii) AlkL E₄* E_(a) 319 E_(1a)E_(ii)E_(iib) AlkL E₄* E_(a) 320 E_(1b)E_(ii)E_(iib) AlkL E₄* E_(a) 321 E_(1a)E₄ AlkL E₄* E_(a) 322 E_(1b)E₄ AlkL E₄* E_(a) 323 E_(1a)E_(i)E₄ AlkL E₄* E_(a) 324 E_(1b)E_(i)E₄ AlkL E₄* E_(a) 325 E_(1a)E_(ii)E₄ AlkL E₄* E_(a) 326 E_(1b)E_(ii)E₄ AlkL E₄* E_(a) 327 E_(1a)E_(ii)E_(iib)E₄ AlkL E₄* E_(a) 328 E_(1b)E_(ii)E_(iib)E₄ AlkL E₄* E_(a) 329 E_(1a)E_(iii) AlkL E₄* E_(a) 330 E_(1b)E_(iii) AlkL E₄* E_(a) 331 E_(1a)E_(iii)E₄ AlkL E₄* E_(a) 332 E_(1b)E_(iii)E₄ AlkL E₄* E_(a) 333 E_(1a)E_(iv) AlkL E₄* E_(a) 334 E_(1b)E_(iv) AlkL E₄* E_(a) 335 E_(1a)E_(iv)E₄ AlkL E₄* E_(a) 336 E_(1b)E_(iv)E₄ AlkL E₄* E_(a) 337 E_(1a) AlkL E₅ E_(a) 338 E_(1b) AlkL E₅ E_(a) 339 E_(1a)E_(i) AlkL E₅ E_(a) 340 E_(1b)E_(i) AlkL E₅ E_(a) 341 E_(1a)E_(ii) AlkL E₅ E_(a) 342 E_(1b)E_(ii) AlkL E₅ E_(a) 343 E_(1a)E_(ii)E_(iib) AlkL E₅ E_(a) 344 E_(1b)E_(ii)E_(iib) AlkL E₅ E_(a) 345 E_(1a)E₄ AlkL E₅ E_(a) 346 E_(1b)E₄ AlkL E₅ E_(a) 347 E_(1a)E_(i)E₄ AlkL E₅ E_(a) 348 E_(1b)E_(i)E₄ AlkL E₅ E_(a) 349 E_(1a)E_(ii)E₄ AlkL E₅ E_(a) 350 E_(1b)E_(ii)E₄ AlkL E₅ E_(a) 351 E_(1a)E_(ii)E_(iib)E₄ AlkL E₅ E_(a) 352 E_(1b)E_(ii)E_(iib)E₄ AlkL E₅ E_(a) 353 E_(1a)E_(iii) AlkL E₅ E_(a) 354 E_(1b)E_(iii) AlkL E₅ E_(a) 355 E_(1a)E_(iii)E₄ AlkL E₅ E_(a) 356 E_(1b)E_(iii)E₄ AlkL E₅ E_(a) 357 E_(1a)E_(iv) AlkL E₅ E_(a) 358 E_(1b)E_(iv) AlkL E₅ E_(a) 359 E_(1a)E_(iv)E₄ AlkL E₅ E_(a) 360 E_(1b)E_(iv)E₄ AlkL E₅ E_(a) 361 E_(1a) AlkL E₄*E₅ E_(a) 362 E_(1b) AlkL E₄*E₅ E_(a) 363 E_(1a)E_(i) AlkL E₄*E₅ E_(a) 364 E_(1b)E_(i) AlkL E₄*E₅ E_(a) 365 E_(1a)E_(ii) AlkL E₄*E₅ E_(a) 366 E_(1b)E_(ii) AlkL E₄*E₅ E_(a) 367 E_(1a)E_(ii)E_(iib) AlkL E₄*E₅ E_(a) 368 E_(1b)E_(ii)E_(iib) AlkL E₄*E₅ E_(a) 369 E_(1a)E₄ AlkL E₄*E₅ E_(a) 370 E_(1b)E₄ AlkL E₄*E₅ E_(a) 371 E_(1a)E_(i)E₄ AlkL E₄*E₅ E_(a) 372 E_(1b)E_(i)E₄ AlkL E₄*E₅ E_(a) 373 E_(1a)E_(ii)E₄ AlkL E₄*E₅ E_(a) 374 E_(1b)E_(ii)E₄ AlkL E₄*E₅ E_(a) 375 E_(1a)E_(ii)E_(iib)E₄ AlkL E₄*E₅ E_(a) 376 E_(1b)E_(ii)E_(iib)E₄ AlkL E₄*E₅ E_(a) 377 E_(1a)E_(iii) AlkL E₄*E₅ E_(a) 378 E_(1b)E_(iii) AlkL E₄*E₅ E_(a) 379 E_(1a)E_(iii)E₄ AlkL E₄*E₅ E_(a) 380 E_(1b)E_(iii)E₄ AlkL E₄*E₅ E_(a) 381 E_(1a)E_(iv) AlkL E₄*E₅ E_(a) 382 E_(1b)E_(iv) AlkL E₄*E₅ E_(a) 383 E_(1a)E_(iv)E₄ AlkL E₄*E₅ E_(a) 384 E_(1b)E_(iv)E₄ AlkL E₄*E₅ E_(a) 385 E_(1a) E_(b) 386 E_(1b) E_(b) 387 E_(1a)E_(i) E_(b) 388 E_(1b)E_(i) E_(b) 389 E_(1a)E_(ii) E_(b) 390 E_(1b)E_(ii) E_(b) 391 E_(1a)E_(ii)E_(iib) E_(b) 392 E_(1b)E_(ii)E_(iib) E_(b) 393 E_(1a)E₄ E_(b) 394 E_(1b)E₄ E_(b) 395 E_(1a)E_(i)E₄ E_(b) 396 E_(1b)E_(i)E₄ E_(b) 397 E_(1a)E_(ii)E₄ E_(b) 398 E_(1b)E_(ii)E₄ E_(b) 399 E_(1a)E_(ii)E_(iib)E₄ E_(b) 400 E_(1b)E_(ii)E_(iib)E₄ E_(b) 401 E_(1a)E_(iii) E_(b) 402 E_(1b)E_(iii) E_(b) 403 E_(1a)E_(iii)E₄ E_(b) 404 E_(1b)E_(iii)E₄ E_(b) 405 E_(1a)E_(iv) E_(b) 406 E_(1b)E_(iv) E_(b) 407 E_(1a)E_(iv)E₄ E_(b) 408 E_(1b)E_(iv)E₄ E_(b) 409 E_(1a) E₄* E_(b) 410 E_(1b) E₄* E_(b) 411 E_(1a)E_(i) E₄* E_(b) 412 E_(1b)E_(i) E₄* E_(b) 413 E_(1a)E_(ii) E₄* E_(b) 414 E_(1b)E_(ii) E₄* E_(b) 415 E_(1a)E_(ii)E_(iib) E₄* E_(b) 416 E_(1b)E_(ii)E_(iib) E₄* E_(b) 417 E_(1a)E₄ E₄* E_(b) 418 E_(1b)E₄ E₄* E_(b) 419 E_(1a)E_(i)E₄ E₄* E_(b) 420 E_(1b)E_(i)E₄ E₄* E_(b) 421 E_(1a)E_(ii)E₄ E₄* E_(b) 422 E_(1b)E_(ii)E₄ E₄* E_(b) 423 E_(1a)E_(ii)E_(iib)E₄ E₄* E_(b) 424 E_(1b)E_(ii)E_(iib)E₄ E₄* E_(b) 425 E_(1a)E_(iii) E₄* E_(b) 426 E_(1b)E_(iii) E₄* E_(b) 427 E_(1a)E_(iii)E₄ E₄* E_(b) 428 E_(1b)E_(iii)E₄ E₄* E_(b) 429 E_(1a)E_(iv) E₄* E_(b) 430 E_(1b)E_(iv) E₄* E_(b) 431 E_(1a)E_(iv)E₄ E₄* E_(b) 432 E_(1b)E_(iv)E₄ E₄* E_(b) 433 E_(1a) E₅ E_(b) 434 E_(1b) E₅ E_(b) 435 E_(1a)E_(i) E₅ E_(b) 436 E_(1b)E_(i) E₅ E_(b) 437 E_(1a)E_(ii) E₅ E_(b) 438 E_(1b)E_(ii) E₅ E_(b) 439 E_(1a)E_(ii)E_(iib) E₅ E_(b) 440 E_(1b)E_(ii)E_(iib) E₅ E_(b) 441 E_(1a)E₄ E₅ E_(b) 442 E_(1b)E₄ E₅ E_(b) 443 E_(1a)E_(i)E₄ E₅ E_(b) 444 E_(1b)E_(i)E₄ E₅ E_(b) 445 E_(1a)E_(ii)E₄ E₅ E_(b) 446 E_(1b)E_(ii)E₄ E₅ E_(b) 447 E_(1a)E_(ii)E_(iib)E₄ E₅ E_(b) 448 E_(1b)E_(ii)E_(iib)E₄ E₅ E_(b) 449 E_(1a)E_(iii) E₅ E_(b) 450 E_(1b)E_(iii) E₅ E_(b) 451 E_(1a)E_(iii)E₄ E₅ E_(b) 452 E_(1b)E_(iii)E₄ E₅ E_(b) 453 E_(1a)E_(iv) E₅ E_(b) 454 E_(1b)E_(iv) E₅ E_(b) 455 E_(1a)E_(iv)E₄ E₅ E_(b) 456 E_(1b)E_(iv)E₄ E₅ E_(b) 457 E_(1a) E₄*E₅ E_(b) 458 E_(1b) E₄*E₅ E_(b) 459 E_(1a)E_(i) E₄*E₅ E_(b) 460 E_(1b)E_(i) E₄*E₅ E_(b) 461 E_(1a)E_(ii) E₄*E₅ E_(b) 462 E_(1b)E_(ii) E₄*E₅ E_(b) 463 E_(1a)E_(ii)E_(iib) E₄*E₅ E_(b) 464 E_(1b)E_(ii)E_(iib) E₄*E₅ E_(b) 465 E_(1a)E₄ E₄*E₅ E_(b) 466 E_(1b)E₄ E₄*E₅ E_(b) 467 E_(1a)E_(i)E₄ E₄*E₅ E_(b) 468 E_(1b)E_(i)E₄ E₄*E₅ E_(b) 469 E_(1a)E_(ii)E₄ E₄*E₅ E_(b) 470 E_(1b)E_(ii)E₄ E₄*E₅ E_(b) 471 E_(1a)E_(ii)E_(iib)E₄ E₄*E₅ E_(b) 472 E_(1b)E_(ii)E_(iib)E₄ E₄*E₅ E_(b) 473 E_(1a)E_(iii) E₄*E₅ E_(b) 474 E_(1b)E_(iii) E₄*E₅ E_(b) 475 E_(1a)E_(iii)E₄ E₄*E₅ E_(b) 476 E_(1b)E_(iii)E₄ E₄*E₅ E_(b) 477 E_(1a)E_(iv) E₄*E₅ E_(b) 478 E_(1b)E_(iv) E₄*E₅ E_(b) 479 E_(1a)E_(iv)E₄ E₄*E₅ E_(b) 480 E_(1b)E_(iv)E₄ E₄*E₅ E_(b) 481 E_(1a) AlkL E_(b) 482 E_(1b) AlkL E_(b) 483 E_(1a)E_(i) AlkL E_(b) 484 E_(1b)E_(i) AlkL E_(b) 485 E_(1a)E_(ii) AlkL E_(b) 486 E_(1b)E_(ii) AlkL E_(b) 487 E_(1a)E_(ii)E_(iib) AlkL E_(b) 488 E_(1b)E_(ii)E_(iib) AlkL E_(b) 489 E_(1a)E₄ AlkL E_(b) 490 E_(1b)E₄ AlkL E_(b) 491 E_(1a)E_(i)E₄ AlkL E_(b) 492 E_(1b)E_(i)E₄ AlkL E_(b) 493 E_(1a)E_(ii)E₄ AlkL E_(b) 494 E_(1b)E_(ii)E₄ AlkL E_(b) 495 E_(1a)E_(ii)E_(iib)E₄ AlkL E_(b) 496 E_(1b)E_(ii)E_(iib)E₄ AlkL E_(b) 497 E_(1a)E_(iii) AlkL E_(b) 498 E_(1b)E_(iii) AlkL E_(b) 499 E_(1a)E_(iii)E₄ AlkL E_(b) 500 E_(1b)E_(iii)E₄ AlkL E_(b) 501 E_(1a)E_(iv) AlkL E_(b) 502 E_(1b)E_(iv) AlkL E_(b) 503 E_(1a)E_(iv)E₄ AlkL E_(b) 504 E_(1b)E_(iv)E₄ AlkL E_(b) 505 E_(1a) AlkL E₄* E_(b) 506 E_(1b) AlkL E₄* E_(b) 507 E_(1a)E_(i) AlkL E₄* E_(b) 508 E_(1b)E_(i) AlkL E₄* E_(b) 509 E_(1a)E_(ii) AlkL E₄* E_(b) 510 E_(1b)E_(ii) AlkL E₄* E_(b) 511 E_(1a)E_(ii)E_(iib) AlkL E₄* E_(b) 512 E_(1b)E_(ii)E_(iib) AlkL E₄* E_(b) 513 E_(1a)E₄ AlkL E₄* E_(b) 514 E_(1b)E₄ AlkL E₄* E_(b) 515 E_(1a)E_(i)E₄ AlkL E₄* E_(b) 516 E_(1b)E_(i)E₄ AlkL E₄* E_(b) 517 E_(1a)E_(ii)E₄ AlkL E₄* E_(b) 518 E_(1b)E_(ii)E₄ AlkL E₄* E_(b) 519 E_(1a)E_(ii)E_(iib)E₄ AlkL E₄* E_(b) 520 E_(1b)E_(ii)E_(iib)E₄ AlkL E₄* E_(b) 521 E_(1a)E_(iii) AlkL E₄* E_(b) 522 E_(1b)E_(iii) AlkL E₄* E_(b) 523 E_(1a)E_(iii)E₄ AlkL E₄* E_(b) 524 E_(1b)E_(iii)E₄ AlkL E₄* E_(b) 525 E_(1a)E_(iv) AlkL E₄* E_(b) 526 E_(1b)E_(iv) AlkL E₄* E_(b) 527 E_(1a)E_(iv)E₄ AlkL E₄* E_(b) 528 E_(1b)E_(iv)E₄ AlkL E₄* E_(b) 529 E_(1a) AlkL E₅ E_(b) 530 E_(1b) AlkL E₅ E_(b) 531 E_(1a)E_(i) AlkL E₅ E_(b) 532 E_(1b)E_(i) AlkL E₅ E_(b) 533 E_(1a)E_(ii) AlkL E₅ E_(b) 534 E_(1b)E_(ii) AlkL E₅ E_(b) 535 E_(1a)E_(ii)E_(iib) AlkL E₅ E_(b) 536 E_(1b)E_(ii)E_(iib) AlkL E₅ E_(b) 537 E_(1a)E₄ AlkL E₅ E_(b) 538 E_(1b)E₄ AlkL E₅ E_(b) 539 E_(1a)E_(i)E₄ AlkL E₅ E_(b) 540 E_(1b)E_(i)E₄ AlkL E₅ E_(b) 541 E_(1a)E_(ii)E₄ AlkL E₅ E_(b) 542 E_(1b)E_(ii)E₄ AlkL E₅ E_(b) 543 E_(1a)E_(ii)E_(iib)E₄ AlkL E₅ E_(b) 544 E_(1b)E_(ii)E_(iib)E₄ AlkL E₅ E_(b) 545 E_(1a)E_(iii) AlkL E₅ E_(b) 546 E_(1b)E_(iii) AlkL E₅ E_(b) 547 E_(1a)E_(iii)E₄ AlkL E₅ E_(b) 548 E_(1b)E_(iii)E₄ AlkL E₅ E_(b) 549 E_(1a)E_(iv) AlkL E₅ E_(b) 550 E_(1b)E_(iv) AlkL E₅ E_(b) 551 E_(1a)E_(iv)E₄ AlkL E₅ E_(b) 552 E_(1b)E_(iv)E₄ AlkL E₅ E_(b) 553 E_(1a) AlkL E₄*E₅ E_(b) 554 E_(1b) AlkL E₄*E₅ E_(b) 555 E_(1a)E_(i) AlkL E₄*E₅ E_(b) 556 E_(1b)E_(i) AlkL E₄*E₅ E_(b) 557 E_(1a)E_(ii) AlkL E₄*E₅ E_(b) 558 E_(1b)E_(ii) AlkL E₄*E₅ E_(b) 559 E_(1a)E_(ii)E_(iib) AlkL E₄*E₅ E_(b) 560 E_(1b)E_(ii)E_(iib) AlkL E₄*E₅ E_(b) 561 E_(1a)E₄ AlkL E₄*E₅ E_(b) 562 E_(1b)E₄ AlkL E₄*E₅ E_(b) 563 E_(1a)E_(i)E₄ AlkL E₄*E₅ E_(b) 564 E_(1b)E_(i)E₄ AlkL E₄*E₅ E_(b) 565 E_(1a)E_(ii)E₄ AlkL E₄*E₅ E_(b) 566 E_(1b)E_(ii)E₄ AlkL E₄*E₅ E_(b) 567 E_(1a)E_(ii)E_(iib)E₄ AlkL E₄*E₅ E_(b) 568 E_(1b)E_(ii)E_(iib)E₄ AlkL E₄*E₅ E_(b) 569 E_(1a)E_(iii) AlkL E₄*E₅ E_(b) 570 E_(1b)E_(iii) AlkL E₄*E₅ E_(b) 571 E_(1a)E_(iii)E₄ AlkL E₄*E₅ E_(b) 572 E_(1b)E_(iii)E₄ AlkL E₄*E₅ E_(b) 573 E_(1a)E_(iv) AlkL E₄*E₅ E_(b) 574 E_(1b)E_(iv) AlkL E₄*E₅ E_(b) 575 E_(1a)E_(iv)E₄ AlkL E₄*E₅ E_(b) 576 E_(1b)E_(iv)E₄ AlkL E₄*E₅ E_(b) 577 E_(1a) E_(d) 578 E_(1b) E_(d) 579 E_(1a)E_(i) E_(d) 580 E_(1b)E_(i) E_(d) 581 E_(1a)E_(ii) E_(d) 582 E_(1b)E_(ii) E_(d) 583 E_(1a)E_(ii)E_(iib) E_(d) 584 E_(1b)E_(ii)E_(iib) E_(d) 585 E_(1a)E₄ E_(d) 586 E_(1b)E₄ E_(d) 587 E_(1a)E_(i)E₄ E_(d) 588 E_(1b)E_(i)E₄ E_(d) 589 E_(1a)E_(ii)E₄ E_(d) 590 E_(1b)E_(ii)E₄ E_(d) 591 E_(1a)E_(ii)E_(iib)E₄ E_(d) 592 E_(1b)E_(ii)E_(iib)E₄ E_(d) 593 E_(1a)E_(iii) E_(d) 594 E_(1b)E_(iii) E_(d) 595 E_(1a)E_(iii)E₄ E_(d) 596 E_(1b)E_(iii)E₄ E_(d) 597 E_(1a)E_(iv) E_(d) 598 E_(1b)E_(iv) E_(d) 599 E_(1a)E_(iv)E₄ E_(d) 600 E_(1b)E_(iv)E₄ E_(d) 601 E_(1a) E₄* E_(d) 602 E_(1b) E₄* E_(d) 603 E_(1a)E_(i) E₄* E_(d) 604 E_(1b)E_(i) E₄* E_(d) 605 E_(1a)E_(ii) E₄* E_(d) 606 E_(1b)E_(ii) E₄* E_(d) 607 E_(1a)E_(ii)E_(iib) E₄* E_(d) 608 E_(1b)E_(ii)E_(iib) E₄* E_(d) 609 E_(1a)E₄ E₄* E_(d) 610 E_(1b)E₄ E₄* E_(d) 611 E_(1a)E_(i)E₄ E₄* E_(d) 612 E_(1b)E_(i)E₄ E₄* E_(d) 613 E_(1a)E_(ii)E₄ E₄* E_(d) 614 E_(1b)E_(ii)E₄ E₄* E_(d) 615 E_(1a)E_(ii)E_(iib)E₄ E₄* E_(d) 616 E_(1b)E_(ii)E_(iib)E₄ E₄* E_(d) 617 E_(1a)E_(iii) E₄* E_(d) 618 E_(1b)E_(iii) E₄* E_(d) 619 E_(1a)E_(iii)E₄ E₄* E_(d) 620 E_(1b)E_(iii)E₄ E₄* E_(d) 621 E_(1a)E_(iv) E₄* E_(d) 622 E_(1b)E_(iv) E₄* E_(d) 623 E_(1a)E_(iv)E₄ E₄* E_(d) 624 E_(1b)E_(iv)E₄ E₄* E_(d) 625 E_(1a) E₅ E_(d) 626 E_(1b) E₅ E_(d) 627 E_(1a)E_(i) E₅ E_(d) 628 E_(1b)E_(i) E₅ E_(d) 629 E_(1a)E_(ii) E₅ E_(d) 630 E_(1b)E_(ii) E₅ E_(d) 631 E_(1a)E_(ii)E_(iib) E₅ E_(d) 632 E_(1b)E_(ii)E_(iib) E₅ E_(d) 633 E_(1a)E₄ E₅ E_(d) 634 E_(1b)E₄ E₅ E_(d) 635 E_(1a)E_(i)E₄ E₅ E_(d) 636 E_(1b)E_(i)E₄ E₅ E_(d) 637 E_(1a)E_(ii)E₄ E₅ E_(d) 638 E_(1b)E_(ii)E₄ E₅ E_(d) 639 E_(1a)E_(ii)E_(iib)E₄ E₅ E_(d) 640 E_(1b)E_(ii)E_(iib)E₄ E₅ E_(d) 641 E_(1a)E_(iii) E₅ E_(d) 642 E_(1b)E_(iii) E₅ E_(d) 643 E_(1a)E_(iii)E₄ E₅ E_(d) 644 E_(1b)E_(iii)E₄ E₅ E_(d) 645 E_(1a)E_(iv) E₅ E_(d) 646 E_(1b)E_(iv) E₅ E_(d) 647 E_(1a)E_(iv)E₄ E₅ E_(d) 648 E_(1b)E_(iv)E₄ E₅ E_(d) 649 E_(1a) E₄*E₅ E_(d) 650 E_(1b) E₄*E₅ E_(d) 651 E_(1a)E_(i) E₄*E₅ E_(d) 652 E_(1b)E_(i) E₄*E₅ E_(d) 653 E_(1a)E_(ii) E₄*E₅ E_(d) 654 E_(1b)E_(ii) E₄*E₅ E_(d) 655 E_(1a)E_(ii)E_(iib) E₄*E₅ E_(d) 656 E_(1b)E_(ii)E_(iib) E₄*E₅ E_(d) 657 E_(1a)E₄ E₄*E₅ E_(d) 658 E_(1b)E₄ E₄*E₅ E_(d) 659 E_(1a)E_(i)E₄ E₄*E₅ E_(d) 660 E_(1b)E_(i)E₄ E₄*E₅ E_(d) 661 E_(1a)E_(ii)E₄ E₄*E₅ E_(d) 662 E_(1b)E_(ii)E₄ E₄*E₅ E_(d) 663 E_(1a)E_(ii)E_(iib)E₄ E₄*E₅ E_(d) 664 E_(1b)E_(ii)E_(iib)E₄ E₄*E₅ E_(d) 665 E_(1a)E_(iii) E₄*E₅ E_(d) 666 E_(1b)E_(iii) E₄*E₅ E_(d) 667 E_(1a)E_(iii)E₄ E₄*E₅ E_(d) 668 E_(1b)E_(iii)E₄ E₄*E₅ E_(d) 669 E_(1a)E_(iv) E₄*E₅ E_(d) 670 E_(1b)E_(iv) E₄*E₅ E_(d) 671 E_(1a)E_(iv)E₄ E₄*E₅ E_(d) 672 E_(1b)E_(iv)E₄ E₄*E₅ E_(d) 673 E_(1a) AlkL E_(d) 674 E_(1b) AlkL E_(d) 675 E_(1a)E_(i) AlkL E_(d) 676 E_(1b)E_(i) AlkL E_(d) 677 E_(1a)E_(ii) AlkL E_(d) 678 E_(1b)E_(ii) AlkL E_(d) 679 E_(1a)E_(ii)E_(iib) AlkL E_(d) 680 E_(1b)E_(ii)E_(iib) AlkL E_(d) 681 E_(1a)E₄ AlkL E_(d) 682 E_(1b)E₄ AlkL E_(d) 683 E_(1a)E_(i)E₄ AlkL E_(d) 684 E_(1b)E_(i)E₄ AlkL E_(d) 685 E_(1a)E_(ii)E₄ AlkL E_(d) 686 E_(1b)E_(ii)E₄ AlkL E_(d) 687 E_(1a)E_(ii)E_(iib)E₄ AlkL E_(d) 688 E_(1b)E_(ii)E_(iib)E₄ AlkL E_(d) 689 E_(1a)E_(iii) AlkL E_(d) 690 E_(1b)E_(iii) AlkL E_(d) 691 E_(1a)E_(iii)E₄ AlkL E_(d) 692 E_(1b)E_(iii)E₄ AlkL E_(d) 693 E_(1a)E_(iv) AlkL E_(d) 694 E_(1b)E_(iv) AlkL E_(d) 695 E_(1a)E_(iv)E₄ AlkL E_(d) 696 E_(1b)E_(iv)E₄ AlkL E_(d) 697 E_(1a) AlkL E₄* E_(d) 698 E_(1b) AlkL E₄* E_(d) 699 E_(1a)E_(i) AlkL E₄* E_(d) 700 E_(1b)E_(i) AlkL E₄* E_(d) 701 E_(1a)E_(ii) AlkL E₄* E_(d) 702 E_(1b)E_(ii) AlkL E₄* E_(d) 703 E_(1a)E_(ii)E_(iib) AlkL E₄* E_(d) 704 E_(1b)E_(ii)E_(iib) AlkL E₄* E_(d) 705 E_(1a)E₄ AlkL E₄* E_(d) 706 E_(1b)E₄ AlkL E₄* E_(d) 707 E_(1a)E_(i)E₄ AlkL E₄* E_(d) 708 E_(1b)E_(i)E₄ AlkL E₄* E_(d) 709 E_(1a)E_(ii)E₄ AlkL E₄* E_(d) 710 E_(1b)E_(ii)E₄ AlkL E₄* E_(d) 711 E_(1a)E_(ii)E_(iib)E₄ AlkL E₄* E_(d) 712 E_(1b)E_(ii)E_(iib)E₄ AlkL E₄* E_(d) 713 E_(1a)E_(iii) AlkL E₄* E_(d) 714 E_(1b)E_(iii) AlkL E₄* E_(d) 715 E_(1a)E_(iii)E₄ AlkL E₄* E_(d) 716 E_(1b)E_(iii)E₄ AlkL E₄* E_(d) 717 E_(1a)E_(iv) AlkL E₄* E_(d) 718 E_(1b)E_(iv) AlkL E₄* E_(d) 719 E_(1a)E_(iv)E₄ AlkL E₄* E_(d) 720 E_(1b)E_(iv)E₄ AlkL E₄* E_(d) 721 E_(1a) AlkL E₅ E_(d) 722 E_(1b) AlkL E₅ E_(d) 723 E_(1a)E_(i) AlkL E₅ E_(d) 724 E_(1b)E_(i) AlkL E₅ E_(d) 725 E_(1a)E_(ii) AlkL E₅ E_(d) 726 E_(1b)E_(ii) AlkL E₅ E_(d) 727 E_(1a)E_(ii)E_(iib) AlkL E₅ E_(d) 728 E_(1b)E_(ii)E_(iib) AlkL E₅ E_(d) 729 E_(1a)E₄ AlkL E₅ E_(d) 730 E_(1b)E₄ AlkL E₅ E_(d) 731 E_(1a)E_(i)E₄ AlkL E₅ E_(d) 732 E_(1b)E_(i)E₄ AlkL E₅ E_(d) 733 E_(1a)E_(ii)E₄ AlkL E₅ E_(d) 734 E_(1b)E_(ii)E₄ AlkL E₅ E_(d) 735 E_(1a)E_(ii)E_(iib)E₄ AlkL E₅ E_(d) 736 E_(1b)E_(ii)E_(iib)E₄ AlkL E₅ E_(d) 737 E_(1a)E_(iii) AlkL E₅ E_(d) 738 E_(1b)E_(iii) AlkL E₅ E_(d) 739 E_(1a)E_(iii)E₄ AlkL E₅ E_(d) 740 E_(1b)E_(iii)E₄ AlkL E₅ E_(d) 741 E_(1a)E_(iv) AlkL E₅ E_(d) 742 E_(1b)E_(iv) AlkL E₅ E_(d) 743 E_(1a)E_(iv)E₄ AlkL E₅ E_(d) 744 E_(1b)E_(iv)E₄ AlkL E₅ E_(d) 745 E_(1a) AlkL E₄*E₅ E_(d) 746 E_(1b) AlkL E₄*E₅ E_(d) 747 E_(1a)E_(i) AlkL E₄*E₅ E_(d) 748 E_(1b)E_(i) AlkL E₄*E₅ E_(d) 749 E_(1a)E_(ii) AlkL E₄*E₅ E_(d) 750 E_(1b)E_(ii) AlkL E₄*E₅ E_(d) 751 E_(1a)E_(ii)E_(iib) AlkL E₄*E₅ E_(d) 752 E_(1b)E_(ii)E_(iib) AlkL E₄*E₅ E_(d) 753 E_(1a)E₄ AlkL E₄*E₅ E_(d) 754 E_(1b)E₄ AlkL E₄*E₅ E_(d) 755 E_(1a)E_(i)E₄ AlkL E₄*E₅ E_(d) 756 E_(1b)E_(i)E₄ AlkL E₄*E₅ E_(d) 757 E_(1a)E_(ii)E₄ AlkL E₄*E₅ E_(d) 758 E_(1b)E_(ii)E₄ AlkL E₄*E₅ E_(d) 759 E_(1a)E_(ii)E_(iib)E₄ AlkL E₄*E₅ E_(d) 760 E_(1b)E_(ii)E_(iib)E₄ AlkL E₄*E₅ E_(d) 761 E_(1a)E_(iii) AlkL E₄*E₅ E_(d) 762 E_(1b)E_(iii) AlkL E₄*E₅ E_(d) 763 E_(1a)E_(iii)E₄ AlkL E₄*E₅ E_(d) 764 E_(1b)E_(iii)E₄ AlkL E₄*E₅ E_(d) 765 E_(1a)E_(iv) AlkL E₄*E₅ E_(d) 766 E_(1b)E_(iv) AlkL E₄*E₅ E_(d) 767 E_(1a)E_(iv)E₄ AlkL E₄*E₅ E_(d) 768 E_(1b)E_(iv)E₄ AlkL E₄*E₅ E_(d) 769 E_(1a) E_(e) 770 E_(1b) E_(e) 771 E_(1a)E_(i) E_(e) 772 E_(1b)E_(i) E_(e) 773 E_(1a)E_(ii) E_(e) 774 E_(1b)E_(ii) E_(e) 775 E_(1a)E_(ii)E_(iib) E_(e) 776 E_(1b)E_(ii)E_(iib) E_(e) 777 E_(1a)E₄ E_(e) 778 E_(1b)E₄ E_(e) 779 E_(1a)E_(i)E₄ E_(e) 780 E_(1b)E_(i)E₄ E_(e) 781 E_(1a)E_(ii)E₄ E_(e) 782 E_(1b)E_(ii)E₄ E_(e) 783 E_(1a)E_(ii)E_(iib)E₄ E_(e) 784 E_(1b)E_(ii)E_(iib)E₄ E_(e) 785 E_(1a)E_(iii) E_(e) 786 E_(1b)E_(iii) E_(e) 787 E_(1a)E_(iii)E₄ E_(e) 788 E_(1b)E_(iii)E₄ E_(e) 789 E_(1a)E_(iv) E_(e) 790 E_(1b)E_(iv) E_(e) 791 E_(1a)E_(iv)E₄ E_(e) 792 E_(1b)E_(iv)E₄ E_(e) 793 E_(1a) E₄* E_(e) 794 E_(1b) E₄* E_(e) 795 E_(1a)E_(i) E₄* E_(e) 796 E_(1b)E_(i) E₄* E_(e) 797 E_(1a)E_(ii) E₄* E_(e) 798 E_(1b)E_(ii) E₄* E_(e) 799 E_(1a)E_(ii)E_(iib) E₄* E_(e) 800 E_(1b)E_(ii)E_(iib) E₄* E_(e) 801 E_(1a)E₄ E₄* E_(e) 802 E_(1b)E₄ E₄* E_(e) 803 E_(1a)E_(i)E₄ E₄* E_(e) 804 E_(1b)E_(i)E₄ E₄* E_(e) 805 E_(1a)E_(ii)E₄ E₄* E_(e) 806 E_(1b)E_(ii)E₄ E₄* E_(e) 807 E_(1a)E_(ii)E_(iib)E₄ E₄* E_(e) 808 E_(1b)E_(ii)E_(iib)E₄ E₄* E_(e) 809 E_(1a)E_(iii) E₄* E_(e) 810 E_(1b)E_(iii) E₄* E_(e) 811 E_(1a)E_(iii)E₄ E₄* E_(e) 812 E_(1b)E_(iii)E₄ E₄* E_(e) 813 E_(1a)E_(iv) E₄* E_(e) 814 E_(1b)E_(iv) E₄* E_(e) 815 E_(1a)E_(iv)E₄ E₄* E_(e) 816 E_(1b)E_(iv)E₄ E₄* E_(e) 817 E_(1a) E₅ E_(e) 818 E_(1b) E₅ E_(e) 819 E_(1a)E_(i) E₅ E_(e) 820 E_(1b)E_(i) E₅ E_(e) 821 E_(1a)E_(ii) E₅ E_(e) 822 E_(1b)E_(ii) E₅ E_(e) 823 E_(1a)E_(ii)E_(iib) E₅ E_(e) 824 E_(1b)E_(ii)E_(iib) E₅ E_(e) 825 E_(1a)E₄ E₅ E_(e) 826 E_(1b)E₄ E₅ E_(e) 827 E_(1a)E_(i)E₄ E₅ E_(e) 828 E_(1b)E_(i)E₄ E₅ E_(e) 829 E_(1a)E_(ii)E₄ E₅ E_(e) 830 E_(1b)E_(ii)E₄ E₅ E_(e) 831 E_(1a)E_(ii)E_(iib)E₄ E₅ E_(e) 832 E_(1b)E_(ii)E_(iib)E₄ E₅ E_(e) 833 E_(1a)E_(iii) E₅ E_(e) 834 E_(1b)E_(iii) E₅ E_(e) 835 E_(1a)E_(iii)E₄ E₅ E_(e) 836 E_(1b)E_(iii)E₄ E₅ E_(e) 837 E_(1a)E_(iv) E₅ E_(e) 838 E_(1b)E_(iv) E₅ E_(e) 839 E_(1a)E_(iv)E₄ E₅ E_(e) 840 E_(1b)E_(iv)E₄ E₅ E_(e) 841 E_(1a) E₄*E₅ E_(e) 842 E_(1b) E₄*E₅ E_(e) 843 E_(1a)E_(i) E₄*E₅ E_(e) 844 E_(1b)E_(i) E₄*E₅ E_(e) 845 E_(1a)E_(ii) E₄*E₅ E_(e) 846 E_(1b)E_(ii) E₄*E₅ E_(e) 847 E_(1a)E_(ii)E_(iib) E₄*E₅ E_(e) 848 E_(1b)E_(ii)E_(iib) E₄*E₅ E_(e) 849 E_(1a)E₄ E₄*E₅ E_(e) 850 E_(1b)E₄ E₄*E₅ E_(e) 851 E_(1a)E_(i)E₄ E₄*E₅ E_(e) 852 E_(1b)E_(i)E₄ E₄*E₅ E_(e) 853 E_(1a)E_(ii)E₄ E₄*E₅ E_(e) 854 E_(1b)E_(ii)E₄ E₄*E₅ E_(e) 855 E_(1a)E_(ii)E_(iib)E₄ E₄*E₅ E_(e) 856 E_(1b)E_(ii)E_(iib)E₄ E₄*E₅ E_(e) 857 E_(1a)E_(iii) E₄*E₅ E_(e) 858 E_(1b)E_(iii) E₄*E₅ E_(e) 859 E_(1a)E_(iii)E₄ E₄*E₅ E_(e) 860 E_(1b)E_(iii)E₄ E₄*E₅ E_(e) 861 E_(1a)E_(iv) E₄*E₅ E_(e) 862 E_(1b)E_(iv) E₄*E₅ E_(e) 863 E_(1a)E_(iv)E₄ E₄*E₅ E_(e) 864 E_(1b)E_(iv)E₄ E₄*E₅ E_(e) 865 E_(1a) AlkL E_(e) 866 E_(1b) AlkL E_(e) 867 E_(1a)E_(i) AlkL E_(e) 868 E_(1b)E_(i) AlkL E_(e) 869 E_(1a)E_(ii) AlkL E_(e) 870 E_(1b)E_(ii) AlkL E_(e) 871 E_(1a)E_(ii)E_(iib) AlkL E_(e) 872 E_(1b)E_(ii)E_(iib) AlkL E_(e) 873 E_(1a)E₄ AlkL E_(e) 874 E_(1b)E₄ AlkL E_(e) 875 E_(1a)E_(i)E₄ AlkL E_(e) 876 E_(1b)E_(i)E₄ AlkL E_(e) 877 E_(1a)E_(ii)E₄ AlkL E_(e) 878 E_(1b)E_(ii)E₄ AlkL E_(e) 879 E_(1a)E_(ii)E_(iib)E₄ AlkL E_(e) 880 E_(1b)E_(ii)E_(iib)E₄ AlkL E_(e) 881 E_(1a)E_(iii) AlkL E_(e) 882 E_(1b)E_(iii) AlkL E_(e) 883 E_(1a)E_(iii)E₄ AlkL E_(e) 884 E_(1b)E_(iii)E₄ AlkL E_(e) 885 E_(1a)E_(iv) AlkL E_(e) 886 E_(1b)E_(iv) AlkL E_(e) 887 E_(1a)E_(iv)E₄ AlkL E_(e) 888 E_(1b)E_(iv)E₄ AlkL E_(e) 889 E_(1a) AlkL E₄* E_(e) 890 E_(1b) AlkL E₄* E_(e) 891 E_(1a)E_(i) AlkL E₄* E_(e) 892 E_(1b)E_(i) AlkL E₄* E_(e) 893 E_(1a)E_(ii) AlkL E₄* E_(e) 894 E_(1b)E_(ii) AlkL E₄* E_(e) 895 E_(1a)E_(ii)E_(iib) AlkL E₄* E_(e) 896 E_(1b)E_(ii)E_(iib) AlkL E₄* E_(e) 897 E_(1a)E₄ AlkL E₄* E_(e) 898 E_(1b)E₄ AlkL E₄* E_(e) 899 E_(1a)E_(i)E₄ AlkL E₄* E_(e) 900 E_(1b)E_(i)E₄ AlkL E₄* E_(e) 901 E_(1a)E_(ii)E₄ AlkL E₄* E_(e) 902 E_(1b)E_(ii)E₄ AlkL E₄* E_(e) 903 E_(1a)E_(ii)E_(iib)E₄ AlkL E₄* E_(e) 904 E_(1b)E_(ii)E_(iib)E₄ AlkL E₄* E_(e) 905 E_(1a)E_(iii) AlkL E₄* E_(e) 906 E_(1b)E_(iii) AlkL E₄* E_(e) 907 E_(1a)E_(iii)E₄ AlkL E₄* E_(e) 908 E_(1b)E_(iii)E₄ AlkL E₄* E_(e) 909 E_(1a)E_(iv) AlkL E₄* E_(e) 910 E_(1b)E_(iv) AlkL E₄* E_(e) 911 E_(1a)E_(iv)E₄ AlkL E₄* E_(e) 912 E_(1b)E_(iv)E₄ AlkL E₄* E_(e) 913 E_(1a) AlkL E₅ E_(e) 914 E_(1b) AlkL E₅ E_(e) 915 E_(1a)E_(i) AlkL E₅ E_(e) 916 E_(1b)E_(i) AlkL E₅ E_(e) 917 E_(1a)E_(ii) AlkL E₅ E_(e) 918 E_(1b)E_(ii) AlkL E₅ E_(e) 919 E_(1a)E_(ii)E_(iib) AlkL E₅ E_(e) 920 E_(1b)E_(ii)E_(iib) AlkL E₅ E_(e) 921 E_(1a)E₄ AlkL E₅ E_(e) 922 E_(1b)E₄ AlkL E₅ E_(e) 923 E_(1a)E_(i)E₄ AlkL E₅ E_(e) 924 E_(1b)E_(i)E₄ AlkL E₅ E_(e) 925 E_(1a)E_(ii)E₄ AlkL E₅ E_(e) 926 E_(1b)E_(ii)E₄ AlkL E₅ E_(e) 927 E_(1a)E_(ii)E_(iib)E₄ AlkL E₅ E_(e) 928 E_(1b)E_(ii)E_(iib)E₄ AlkL E₅ E_(e) 929 E_(1a)E_(iii) AlkL E₅ E_(e) 930 E_(1b)E_(iii) AlkL E₅ E_(e) 931 E_(1a)E_(iii)E₄ AlkL E₅ E_(e) 932 E_(1b)E_(iii)E₄ AlkL E₅ E_(e) 933 E_(1a)E_(iv) AlkL E₅ E_(e) 934 E_(1b)E_(iv) AlkL E₅ E_(e) 935 E_(1a)E_(iv)E₄ AlkL E₅ E_(e) 936 E_(1b)E_(iv)E₄ AlkL E₅ E_(e) 937 E_(1a) AlkL E₄*E₅ E_(e) 938 E_(1b) AlkL E₄*E₅ E_(e) 939 E_(1a)E_(i) AlkL E₄*E₅ E_(e) 940 E_(1b)E_(i) AlkL E₄*E₅ E_(e) 941 E_(1a)E_(ii) AlkL E₄*E₅ E_(e) 942 E_(1b)E_(ii) AlkL E₄*E₅ E_(e) 943 E_(1a)E_(ii)E_(iib) AlkL E₄*E₅ E_(e) 944 E_(1b)E_(ii)E_(iib) AlkL E₄*E₅ E_(e) 945 E_(1a)E₄ AlkL E₄*E₅ E_(e) 946 E_(1b)E₄ AlkL E₄*E₅ E_(e) 947 E_(1a)E_(i)E₄ AlkL E₄*E₅ E_(e) 948 E_(1b)E_(i)E₄ AlkL E₄*E₅ E_(e) 949 E_(1a)E_(ii)E₄ AlkL E₄*E₅ E_(e) 950 E_(1b)E_(ii)E₄ AlkL E₄*E₅ E_(e) 951 E_(1a)E_(ii)E_(iib)E₄ AlkL E₄*E₅ E_(e) 952 E_(1b)E_(ii)E_(iib)E₄ AlkL E₄*E₅ E_(e) 953 E_(1a)E_(iii) AlkL E₄*E₅ E_(e) 954 E_(1b)E_(iii) AlkL E₄*E₅ E_(e) 955 E_(1a)E_(iii)E₄ AlkL E₄*E₅ E_(e) 956 E_(1b)E_(iii)E₄ AlkL E₄*E₅ E_(e) 957 E_(1a)E_(iv) AlkL E₄*E₅ E_(e) 958 E_(1b)E_(iv) AlkL E₄*E₅ E_(e) 959 E_(1a)E_(iv)E₄ AlkL E₄*E₅ E_(e) 960 E_(1b)E_(iv)E₄ AlkL E₄*E₅ E_(e) 961 E_(1a) E_(f) 962 E_(1b) E_(f) 963 E_(1a)E_(i) E_(f) 964 E_(1b)E_(i) E_(f) 965 E_(1a)E_(ii) E_(f) 966 E_(1b)E_(ii) E_(f) 967 E_(1a)E_(ii)E_(iib) E_(f) 968 E_(1b)E_(ii)E_(iib) E_(f) 969 E_(1a)E₄ E_(f) 970 E_(1b)E₄ E_(f) 971 E_(1a)E_(i)E₄ E_(f) 972 E_(1b)E_(i)E₄ E_(f) 973 E_(1a)E_(ii)E₄ E_(f) 974 E_(1b)E_(ii)E₄ E_(f) 975 E_(1a)E_(ii)E_(iib)E₄ E_(f) 976 E_(1b)E_(ii)E_(iib)E₄ E_(f) 977 E_(1a)E_(iii) E_(f) 978 E_(1b)E_(iii) E_(f) 979 E_(1a)E_(iii)E₄ E_(f) 980 E_(1b)E_(iii)E₄ E_(f) 981 E_(1a)E_(iv) E_(f) 982 E_(1b)E_(iv) E_(f) 983 E_(1a)E_(iv)E₄ E_(f) 984 E_(1b)E_(iv)E₄ E_(f) 985 E_(1a) E₄* E_(f) 986 E_(1b) E₄* E_(f) 987 E_(1a)E_(i) E₄* E_(f) 988 E_(1b)E_(i) E₄* E_(f) 989 E_(1a)E_(ii) E₄* E_(f) 990 E_(1b)E_(ii) E₄* E_(f) 991 E_(1a)E_(ii)E_(iib) E₄* E_(f) 992 E_(1b)E_(ii)E_(iib) E₄* E_(f) 993 E_(1a)E₄ E₄* E_(f) 994 E_(1b)E₄ E₄* E_(f) 995 E_(1a)E_(i)E₄ E₄* E_(f) 996 E_(1b)E_(i)E₄ E₄* E_(f) 997 E_(1a)E_(ii)E₄ E₄* E_(f) 998 E_(1b)E_(ii)E₄ E₄* E_(f) 999 E_(1a)E_(ii)E_(iib)E₄ E₄* E_(f) 1000 E_(1b)E_(ii)E_(iib)E₄ E₄* E_(f) 1001 E_(1a)E_(iii) E₄* E_(f) 1002 E_(1b)E_(iii) E₄* E_(f) 1003 E_(1a)E_(iii)E₄ E₄* E_(f) 1004 E_(1b)E_(iii)E₄ E₄* E_(f) 1005 E_(1a)E_(iv) E₄* E_(f) 1006 E_(1b)E_(iv) E₄* E_(f) 1007 E_(1a)E_(iv)E₄ E₄* E_(f) 1008 E_(1b)E_(iv)E₄ E₄* E_(f) 1009 E_(1a) E₅ E_(f) 1010 E_(1b) E₅ E_(f) 1011 E_(1a)E_(i) E₅ E_(f) 1012 E_(1b)E_(i) E₅ E_(f) 1013 E_(1a)E_(ii) E₅ E_(f) 1014 E_(1b)E_(ii) E₅ E_(f) 1015 E_(1a)E_(ii)E_(iib) E₅ E_(f) 1016 E_(1b)E_(ii)E_(iib) E₅ E_(f) 1017 E_(1a)E₄ E₅ E_(f) 1018 E_(1b)E₄ E₅ E_(f) 1019 E_(1a)E_(i)E₄ E₅ E_(f) 1020 E_(1b)E_(i)E₄ E₅ E_(f) 1021 E_(1a)E_(ii)E₄ E₅ E_(f) 1022 E_(1b)E_(ii)E₄ E₅ E_(f) 1023 E_(1a)E_(ii)E_(iib)E₄ E₅ E_(f) 1024 E_(1b)E_(ii)E_(iib)E₄ E₅ E_(f) 1025 E_(1a)E_(iii) E₅ E_(f) 1026 E_(1b)E_(iii) E₅ E_(f) 1027 E_(1a)E_(iii)E₄ E₅ E_(f) 1028 E_(1b)E_(iii)E₄ E₅ E_(f) 1029 E_(1a)E_(iv) E₅ E_(f) 1030 E_(1b)E_(iv) E₅ E_(f) 1031 E_(1a)E_(iv)E₄ E₅ E_(f) 1032 E_(1b)E_(iv)E₄ E₅ E_(f) 1033 E_(1a) E₄*E₅ E_(f) 1034 E_(1b) E₄*E₅ E_(f) 1035 E_(1a)E_(i) E₄*E₅ E_(f) 1036 E_(1b)E_(i) E₄*E₅ E_(f) 1037 E_(1a)E_(ii) E₄*E₅ E_(f) 1038 E_(1b)E_(ii) E₄*E₅ E_(f) 1039 E_(1a)E_(ii)E_(iib) E₄*E₅ E_(f) 1040 E_(1b)E_(ii)E_(iib) E₄*E₅ E_(f) 1041 E_(1a)E₄ E₄*E₅ E_(f) 1042 E_(1b)E₄ E₄*E₅ E_(f) 1043 E_(1a)E_(i)E₄ E₄*E₅ E_(f) 1044 E_(1b)E_(i)E₄ E₄*E₅ E_(f) 1045 E_(1a)E_(ii)E₄ E₄*E₅ E_(f) 1046 E_(1b)E_(ii)E₄ E₄*E₅ E_(f) 1047 E_(1a)E_(ii)E_(iib)E₄ E₄*E₅ E_(f) 1048 E_(1b)E_(ii)E_(iib)E₄ E₄*E₅ E_(f) 1049 E_(1a)E_(iii) E₄*E₅ E_(f) 1050 E_(1b)E_(iii) E₄*E₅ E_(f) 1051 E_(1a)E_(iii)E₄ E₄*E₅ E_(f) 1052 E_(1b)E_(iii)E₄ E₄*E₅ E_(f) 1053 E_(1a)E_(iv) E₄*E₅ E_(f) 1054 E_(1b)E_(iv) E₄*E₅ E_(f) 1055 E_(1a)E_(iv)E₄ E₄*E₅ E_(f) 1056 E_(1b)E_(iv)E₄ E₄*E₅ E_(f) 1057 E_(1a) AlkL E_(f) 1058 E_(1b) AlkL E_(f) 1059 E_(1a)E_(i) AlkL E_(f) 1060 E_(1b)E_(i) AlkL E_(f) 1061 E_(1a)E_(ii) AlkL E_(f) 1062 E_(1b)E_(ii) AlkL E_(f) 1063 E_(1a)E_(ii)E_(iib) AlkL E_(f) 1064 E_(1b)E_(ii)E_(iib) AlkL E_(f) 1065 E_(1a)E₄ AlkL E_(f) 1066 E_(1b)E₄ AlkL E_(f) 1067 E_(1a)E_(i)E₄ AlkL E_(f) 1068 E_(1b)E_(i)E₄ AlkL E_(f) 1069 E_(1a)E_(ii)E₄ AlkL E_(f) 1070 E_(1b)E_(ii)E₄ AlkL E_(f) 1071 E_(1a)E_(ii)E_(iib)E₄ AlkL E_(f) 1072 E_(1b)E_(ii)E_(iib)E₄ AlkL E_(f) 1073 E_(1a)E_(iii) AlkL E_(f) 1074 E_(1b)E_(iii) AlkL E_(f) 1075 E_(1a)E_(iii)E₄ AlkL E_(f) 1076 E_(1b)E_(iii)E₄ AlkL E_(f) 1077 E_(1a)E_(iv) AlkL E_(f) 1078 E_(1b)E_(iv) AlkL E_(f) 1079 E_(1a)E_(iv)E₄ AlkL E_(f) 1080 E_(1b)E_(iv)E₄ AlkL E_(f) 1081 E_(1a) AlkL E₄* E_(f) 1082 E_(1b) AlkL E₄* E_(f) 1083 E_(1a)E_(i) AlkL E₄* E_(f) 1084 E_(1b)E_(i) AlkL E₄* E_(f) 1085 E_(1a)E_(ii) AlkL E₄* E_(f) 1086 E_(1b)E_(ii) AlkL E₄* E_(f) 1087 E_(1a)E_(ii)E_(iib) AlkL E₄* E_(f) 1088 E_(1b)E_(ii)E_(iib) AlkL E₄* E_(f) 1089 E_(1a)E₄ AlkL E₄* E_(f) 1090 E_(1b)E₄ AlkL E₄* E_(f) 1091 E_(1a)E_(i)E₄ AlkL E₄* E_(f) 1092 E_(1b)E_(i)E₄ AlkL E₄* E_(f) 1093 E_(1a)E_(ii)E₄ AlkL E₄* E_(f) 1094 E_(1b)E_(ii)E₄ AlkL E₄* E_(f) 1095 E_(1a)E_(ii)E_(iib)E₄ AlkL E₄* E_(f) 1096 E_(1b)E_(ii)E_(iib)E₄ AlkL E₄* E_(f) 1097 E_(1a)E_(iii) AlkL E₄* E_(f) 1098 E_(1b)E_(iii) AlkL E₄* E_(f) 1099 E_(1a)E_(iii)E₄ AlkL E₄* E_(f) 1100 E_(1b)E_(iii)E₄ AlkL E₄* E_(f) 1101 E_(1a)E_(iv) AlkL E₄* E_(f) 1102 E_(1b)E_(iv) AlkL E₄* E_(f) 1103 E_(1a)E_(iv)E₄ AlkL E₄* E_(f) 1104 E_(1b)E_(iv)E₄ AlkL E₄* E_(f) 1105 E_(1a) AlkL E₅ E_(f) 1106 E_(1b) AlkL E₅ E_(f) 1107 E_(1a)E_(i) AlkL E₅ E_(f) 1108 E_(1b)E_(i) AlkL E₅ E_(f) 1109 E_(1a)E_(ii) AlkL E₅ E_(f) 1110 E_(1b)E_(ii) AlkL E₅ E_(f) 1111 E_(1a)E_(ii)E_(iib) AlkL E₅ E_(f) 1112 E_(1b)E_(ii)E_(iib) AlkL E₅ E_(f) 1113 E_(1a)E₄ AlkL E₅ E_(f) 1114 E_(1b)E₄ AlkL E₅ E_(f) 1115 E_(1a)E_(i)E₄ AlkL E₅ E_(f) 1116 E_(1b)E_(i)E₄ AlkL E₅ E_(f) 1117 E_(1a)E_(ii)E₄ AlkL E₅ E_(f) 1118 E_(1b)E_(ii)E₄ AlkL E₅ E_(f) 1119 E_(1a)E_(ii)E_(iib)E₄ AlkL E₅ E_(f) 1120 E_(1b)E_(ii)E_(iib)E₄ AlkL E₅ E_(f) 1121 E_(1a)E_(iii) AlkL E₅ E_(f) 1122 E_(1b)E_(iii) AlkL E₅ E_(f) 1123 E_(1a)E_(iii)E₄ AlkL E₅ E_(f) 1124 E_(1b)E_(iii)E₄ AlkL E₅ E_(f) 1125 E_(1a)E_(iv) AlkL E₅ E_(f) 1126 E_(1b)E_(iv) AlkL E₅ E_(f) 1127 E_(1a)E_(iv)E₄ AlkL E₅ E_(f) 1128 E_(1b)E_(iv)E₄ AlkL E₅ E_(f) 1129 E_(1a) AlkL E₄*E₅ E_(f) 1130 E_(1b) AlkL E₄*E₅ E_(f) 1131 E_(1a)E_(i) AlkL E₄*E₅ E_(f) 1132 E_(1b)E_(i) AlkL E₄*E₅ E_(f) 1133 E_(1a)E_(ii) AlkL E₄*E₅ E_(f) 1134 E_(1b)E_(ii) AlkL E₄*E₅ E_(f) 1135 E_(1a)E_(ii)E_(iib) AlkL E₄*E₅ E_(f) 1136 E_(1b)E_(ii)E_(iib) AlkL E₄*E₅ E_(f) 1137 E_(1a)E₄ AlkL E₄*E₅ E_(f) 1138 E_(1b)E₄ AlkL E₄*E₅ E_(f) 1139 E_(1a)E_(i)E₄ AlkL E₄*E₅ E_(f) 1140 E_(1b)E_(i)E₄ AlkL E₄*E₅ E_(f) 1141 E_(1a)E_(ii)E₄ AlkL E₄*E₅ E_(f) 1142 E_(1b)E_(ii)E₄ AlkL E₄*E₅ E_(f) 1143 E_(1a)E_(ii)E_(iib)E₄ AlkL E₄*E₅ E_(f) 1144 E_(1b)E_(ii)E_(iib)E₄ AlkL E₄*E₅ E_(f) 1145 E_(1a)E_(iii) AlkL E₄*E₅ E_(f) 1146 E_(1b)E_(iii) AlkL E₄*E₅ E_(f) 1147 E_(1a)E_(iii)E₄ AlkL E₄*E₅ E_(f) 1148 E_(1b)E_(iii)E₄ AlkL E₄*E₅ E_(f) 1149 E_(1a)E_(iv) AlkL E₄*E₅ E_(f) 1150 E_(1b)E_(iv) AlkL E₄*E₅ E_(f) 1151 E_(1a)E_(iv)E₄ AlkL E₄*E₅ E_(f) 1152 E_(1b)E_(iv)E₄ AlkL E₄*E₅ E_(f)

Microorganisms quite especially preferred according to the invention (abbreviated as MO) are outstandingly suitable for the production of ω-hydroxycarboxylate esters or ω-oxocarboxylate esters and have increased or decreased enzyme activities (abbreviated as E) described in the following table, where these can in addition advantageously be combined with an increased enzyme activity compared to the wild type of the microorganism, which is described for the 3-ketoacyl-ACP (Acyl Carrrier Protein) synthase III (EC 2.3.1.41), in particular that from plants, preferably that from plants the seeds whereof contain fatty acids with alkyl residues shorter than 14 C atoms, and particularly preferably that from plants of the genera Cuphea, Elaeis, Cocos, Umbellularia and Cinnamomum and gene products selected from AccA, AccB, AccC, AccD, AceE, AceF, Lpd, AcpP, FabA, FabB, FabD, FabF, FabG, FabH, FabI, FabZ, PanD, PanK, UdhA, PntA or PntB.

Any combinations of at least two of these enzyme activities can advantageously be increased.

In addition, moreover, it can be advantageous if the microorganism is provided with a lower enzyme activity compared to the wild type of the microorganism, which is described for the gene products selected from TdcE, PflA, PflB, PflC, PflD, PoxB, YgfG, AckA, AckB, TdcD, Pta, LdhA, AdhE, MgsA, FdnG, FdnH, FdnI, FdhF, FdoG, FdoH, FdoI, PrpC, PrpD, PrpF, PrpB, TdcD, Pdc, PorA, PorB, PorC, PorD, AlsS, IlvB, IlvM, IlvN, IlvG, IlyI, IlvH, AlsD, ButB, Thl, ThlA, ThlB, PhaA, PhaB, Crt, BdhA, BdhB, Adc, Adh, CtfB, AtoA, AtoD, LdhL, GltA, FabR, FhuA, Dld, LldA or LldP, singly or in any combination.

MO E increased E decreased 1 E_(1a) E_(v)E_(vi) 2 E_(1b) E_(v)E_(vi) 3 E_(1a)E_(i) E_(v)E_(vi) 4 E_(1b)E_(i) E_(v)E_(vi) 5 E_(1a)E_(ii) E_(v)E_(vi) 6 E_(1b)E_(ii) E_(v)E_(vi) 7 E_(1a)E_(ii)E_(iib) E_(v)E_(vi) 8 E_(1b)E_(ii)E_(iib) E_(v)E_(vi) 9 E_(1a)E₄ E_(v)E_(vi) 10 E_(1b)E₄ E_(v)E_(vi) 11 E_(1a)E_(i)E₄ E_(v)E_(vi) 12 E_(1b)E_(i)E₄ E_(v)E_(vi) 13 E_(1a)E_(ii)E₄ E_(v)E_(vi) 14 E_(1b)E_(ii)E₄ E_(v)E_(vi) 15 E_(1a)E_(ii)E_(iib)E₄ E_(v)E_(vi) 16 E_(1b)E_(ii)E_(iib)E₄ E_(v)E_(vi) 17 E_(1a)E_(iii) E_(v)E_(vi) 18 E_(1b)E_(iii) E_(v)E_(vi) 19 E_(1a)E_(iii)E₄ E_(v)E_(vi) 20 E_(1b)E_(iii)E₄ E_(v)E_(vi) 21 E_(1a)E_(iv) E_(v)E_(vi) 22 E_(1b)E_(iv) E_(v)E_(vi) 23 E_(1a)E_(iv)E₄ E_(v)E_(vi) 24 E_(1b)E_(iv)E₄ E_(v)E_(vi) 25 E_(1a) E_(v)E_(vi) E₄* 26 E_(1b) E_(v)E_(vi) E₄* 27 E_(1a)E_(i) E_(v)E_(vi) E₄* 28 E_(1b)E_(i) E_(v)E_(vi) E₄* 29 E_(1a)E_(ii) E_(v)E_(vi) E₄* 30 E_(1b)E_(ii) E_(v)E_(vi) E₄* 31 E_(1a)E_(ii)E_(iib) E_(v)E_(vi) E₄* 32 E_(1b)E_(ii)E_(iib) E_(v)E_(vi) E₄* 33 E_(1a)E₄ E_(v)E_(vi) E₄* 34 E_(1b)E₄ E_(v)E_(vi) E₄* 35 E_(1a)E_(i)E₄ E_(v)E_(vi) E₄* 36 E_(1b)E_(i)E₄ E_(v)E_(vi) E₄* 37 E_(1a)E_(ii)E₄ E_(v)E_(vi) E₄* 38 E_(1b)E_(ii)E₄ E_(v)E_(vi) E₄* 39 E_(1a)E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* 40 E_(1b)E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* 41 E_(1a)E_(iii) E_(v)E_(vi) E₄* 42 E_(1b)E_(iii) E_(v)E_(vi) E₄* 43 E_(1a)E_(iii)E₄ E_(v)E_(vi) E₄* 44 E_(1b)E_(iii)E₄ E_(v)E_(vi) E₄* 45 E_(1a)E_(iv) E_(v)E_(vi) E₄* 46 E_(1b)E_(iv) E_(v)E_(vi) E₄* 47 E_(1a)E_(iv)E₄ E_(v)E_(vi) E₄* 48 E_(1b)E_(iv)E₄ E_(v)E_(vi) E₄* 49 E_(1a) E_(v)E_(vi) E₅ 50 E_(1b) E_(v)E_(vi) E₅ 51 E_(1a)E_(i) E_(v)E_(vi) E₅ 52 E_(1b)E_(i) E_(v)E_(vi) E₅ 53 E_(1a)E_(ii) E_(v)E_(vi) E₅ 54 E_(1b)E_(ii) E_(v)E_(vi) E₅ 55 E_(1a)E_(ii)E_(iib) E_(v)E_(vi) E₅ 56 E_(1b)E_(ii)E_(iib) E_(v)E_(vi) E₅ 57 E_(1a)E₄ E_(v)E_(vi) E₅ 58 E_(1b)E₄ E_(v)E_(vi) E₅ 59 E_(1a)E_(i)E₄ E_(v)E_(vi) E₅ 60 E_(1b)E_(i)E₄ E_(v)E_(vi) E₅ 61 E_(1a)E_(ii)E₄ E_(v)E_(vi) E₅ 62 E_(1b)E_(ii)E₄ E_(v)E_(vi) E₅ 63 E_(1a)E_(ii)E_(iib)E₄ E_(v)E_(vi) E₅ 64 E_(1b)E_(ii)E_(iib)E₄ E_(v)E_(vi) E₅ 65 E_(1a)E_(iii) E_(v)E_(vi) E₅ 66 E_(1b)E_(iii) E_(v)E_(vi) E₅ 67 E_(1a)E_(iii)E₄ E_(v)E_(vi) E₅ 68 E_(1b)E_(iii)E₄ E_(v)E_(vi) E₅ 69 E_(1a)E_(iv) E_(v)E_(vi) E₅ 70 E_(1b)E_(iv) E_(v)E_(vi) E₅ 71 E_(1a)E_(iv)E₄ E_(v)E_(vi) E₅ 72 E_(1b)E_(iv)E₄ E_(v)E_(vi) E₅ 73 E_(1a) E_(v)E_(vi) E₄*E₅ 74 E_(1b) E_(v)E_(vi) E₄*E₅ 75 E_(1a)E_(i) E_(v)E_(vi) E₄*E₅ 76 E_(1b)E_(i) E_(v)E_(vi) E₄*E₅ 77 E_(1a)E_(ii) E_(v)E_(vi) E₄*E₅ 78 E_(1b)E_(ii) E_(v)E_(vi) E₄*E₅ 79 E_(1a)E_(ii)E_(iib) E_(v)E_(vi) E₄*E₅ 80 E_(1b)E_(ii)E_(iib) E_(v)E_(vi) E₄*E₅ 81 E_(1a)E₄ E_(v)E_(vi) E₄*E₅ 82 E_(1b)E₄ E_(v)E_(vi) E₄*E₅ 83 E_(1a)E_(i)E₄ E_(v)E_(vi) E₄*E₅ 84 E_(1b)E_(i)E₄ E_(v)E_(vi) E₄*E₅ 85 E_(1a)E_(ii)E₄ E_(v)E_(vi) E₄*E₅ 86 E_(1b)E_(ii)E₄ E_(v)E_(vi) E₄*E₅ 87 E_(1a)E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄*E₅ 88 E_(1b)E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄*E₅ 89 E_(1a)E_(iii) E_(v)E_(vi) E₄*E₅ 90 E_(1b)E_(iii) E_(v)E_(vi) E₄*E₅ 91 E_(1a)E_(iii)E₄ E_(v)E_(vi) E₄*E₅ 92 E_(1b)E_(iii)E₄ E_(v)E_(vi) E₄*E₅ 93 E_(1a)E_(iv) E_(v)E_(vi) E₄*E₅ 94 E_(1b)E_(iv) E_(v)E_(vi) E₄*E₅ 95 E_(1a)E_(iv)E₄ E_(v)E_(vi) E₄*E₅ 96 E_(1b)E_(iv)E₄ E_(v)E_(vi) E₄*E₅ 97 E_(1a) AlkLE_(v)E_(vi) 98 E_(1b) AlkLE_(v)E_(vi) 99 E_(1a)E_(i) AlkLE_(v)E_(vi) 100 E_(1b)E_(i) AlkLE_(v)E_(vi) 101 E_(1a)E_(ii) AlkLE_(v)E_(vi) 102 E_(1b)E_(ii) AlkLE_(v)E_(vi) 103 E_(1a)E_(ii)E_(iib) AlkLE_(v)E_(vi) 104 E_(1b)E_(ii)E_(iib) AlkLE_(v)E_(vi) 105 E_(1a)E₄ AlkLE_(v)E_(vi) 106 E_(1b)E₄ AlkLE_(v)E_(vi) 107 E_(1a)E_(i)E₄ AlkLE_(v)E_(vi) 108 E_(1b)E_(i)E₄ AlkLE_(v)E_(vi) 109 E_(1a)E_(ii)E₄ AlkLE_(v)E_(vi) 110 E_(1b)E_(ii)E₄ AlkLE_(v)E_(vi) 111 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) 112 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) 113 E_(1a)E_(iii) AlkLE_(v)E_(vi) 114 E_(1b)E_(iii) AlkLE_(v)E_(vi) 115 E_(1a)E_(iii)E₄ AlkLE_(v)E_(vi) 116 E_(1b)E_(iii)E₄ AlkLE_(v)E_(vi) 117 E_(1a)E_(iv) AlkLE_(v)E_(vi) 118 E_(1b)E_(iv) AlkLE_(v)E_(vi) 119 E_(1a)E_(iv)E₄ AlkLE_(v)E_(vi) 120 E_(1b)E_(iv)E₄ AlkLE_(v)E_(vi) 121 E_(1a) AlkLE_(v)E_(vi) E₄* 122 E_(1b) AlkLE_(v)E_(vi) E₄* 123 E_(1a)E_(i) AlkLE_(v)E_(vi) E₄* 124 E_(1b)E_(i) AlkLE_(v)E_(vi) E₄* 125 E_(1a)E_(ii) AlkLE_(v)E_(vi) E₄* 126 E_(1b)E_(ii) AlkLE_(v)E_(vi) E₄* 127 E_(1a)E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* 128 E_(1b)E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* 129 E_(1a)E₄ AlkLE_(v)E_(vi) E₄* 130 E_(1b)E₄ AlkLE_(v)E_(vi) E₄* 131 E_(1a)E_(i)E₄ AlkLE_(v)E_(vi) E₄* 132 E_(1b)E_(i)E₄ AlkLE_(v)E_(vi) E₄* 133 E_(1a)E_(ii)E₄ AlkLE_(v)E_(vi) E₄* 134 E_(1b)E_(ii)E₄ AlkLE_(v)E_(vi) E₄* 135 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* 136 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* 137 E_(1a)E_(iii) AlkLE_(v)E_(vi) E₄* 138 E_(1b)E_(iii) AlkLE_(v)E_(vi) E₄* 139 E_(1a)E_(iii)E₄ AlkLE_(v)E_(vi) E₄* 140 E_(1b)E_(iii)E₄ AlkLE_(v)E_(vi) E₄* 141 E_(1a)E_(iv) AlkLE_(v)E_(vi) E₄* 142 E_(1b)E_(iv) AlkLE_(v)E_(vi) E₄* 143 E_(1a)E_(iv)E₄ AlkLE_(v)E_(vi) E₄* 144 E_(1b)E_(iv)E₄ AlkLE_(v)E_(vi) E₄* 145 E_(1a) AlkLE_(v)E_(vi) E₅ 146 E_(1b) AlkLE_(v)E_(vi) E₅ 147 E_(1a)E_(i) AlkLE_(v)E_(vi) E₅ 148 E_(1b)E_(i) AlkLE_(v)E_(vi) E₅ 149 E_(1a)E_(ii) AlkLE_(v)E_(vi) E₅ 150 E_(1b)E_(ii) AlkLE_(v)E_(vi) E₅ 151 E_(1a)E_(ii)E_(iib) AlkLE_(v)E_(vi) E₅ 152 E_(1b)E_(ii)E_(iib) AlkLE_(v)E_(vi) E₅ 153 E_(1a)E₄ AlkLE_(v)E_(vi) E₅ 154 E_(1b)E₄ AlkLE_(v)E_(vi) E₅ 155 E_(1a)E_(i)E₄ AlkLE_(v)E_(vi) E₅ 156 E_(1b)E_(i)E₄ AlkLE_(v)E_(vi) E₅ 157 E_(1a)E_(ii)E₄ AlkLE_(v)E_(vi) E₅ 158 E_(1b)E_(ii)E₄ AlkLE_(v)E_(vi) E₅ 159 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₅ 160 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₅ 161 E_(1a)E_(iii) AlkLE_(v)E_(vi) E₅ 162 E_(1b)E_(iii) AlkLE_(v)E_(vi) E₅ 163 E_(1a)E_(iii)E₄ AlkLE_(v)E_(vi) E₅ 164 E_(1b)E_(iii)E₄ AlkLE_(v)E_(vi) E₅ 165 E_(1a)E_(iv) AlkLE_(v)E_(vi) E₅ 166 E_(1b)E_(iv) AlkLE_(v)E_(vi) E₅ 167 E_(1a)E_(iv)E₄ AlkLE_(v)E_(vi) E₅ 168 E_(1b)E_(iv)E₄ AlkLE_(v)E_(vi) E₅ 169 E_(1a) AlkLE_(v)E_(vi) E₄*E₅ 170 E_(1b) AlkLE_(v)E_(vi) E₄*E₅ 171 E_(1a)E_(i) AlkLE_(v)E_(vi) E₄*E₅ 172 E_(1b)E_(i) AlkLE_(v)E_(vi) E₄*E₅ 173 E_(1a)E_(ii) AlkLE_(v)E_(vi) E₄*E₅ 174 E_(1b)E_(ii) AlkLE_(v)E_(vi) E₄*E₅ 175 E_(1a)E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄*E₅ 176 E_(1b)E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄*E₅ 177 E_(1a)E₄ AlkLE_(v)E_(vi) E₄*E₅ 178 E_(1b)E₄ AlkLE_(v)E_(vi) E₄*E₅ 179 E_(1a)E_(i)E₄ AlkLE_(v)E_(vi) E₄*E₅ 180 E_(1b)E_(i)E₄ AlkLE_(v)E_(vi) E₄*E₅ 181 E_(1a)E_(ii)E₄ AlkLE_(v)E_(vi) E₄*E₅ 182 E_(1b)E_(ii)E₄ AlkLE_(v)E_(vi) E₄*E₅ 183 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄*E₅ 184 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄*E₅ 185 E_(1a)E_(iii) AlkLE_(v)E_(vi) E₄*E₅ 186 E_(1b)E_(iii) AlkLE_(v)E_(vi) E₄*E₅ 187 E_(1a)E_(iii)E₄ AlkLE_(v)E_(vi) E₄*E₅ 188 E_(1b)E_(iii)E₄ AlkLE_(v)E_(vi) E₄*E₅ 189 E_(1a)E_(iv) AlkLE_(v)E_(vi) E₄*E₅ 190 E_(1b)E_(iv) AlkLE_(v)E_(vi) E₄*E₅ 191 E_(1a)E_(iv)E₄ AlkLE_(v)E_(vi) E₄*E₅ 192 E_(1b)E_(iv)E₄ AlkLE_(v)E_(vi) E₄*E₅ 193 E_(1a) E_(v)E_(vi) E_(a) 194 E_(1b) E_(v)E_(vi) E_(a) 195 E_(1a)E_(i) E_(v)E_(vi) E_(a) 196 E_(1b)E_(i) E_(v)E_(vi) E_(a) 197 E_(1a)E_(ii) E_(v)E_(vi) E_(a) 198 E_(1b)E_(ii) E_(v)E_(vi) E_(a) 199 E_(1a)E_(ii)E_(iib) E_(v)E_(vi) E_(a) 200 E_(1b)E_(ii)E_(iib) E_(v)E_(vi) E_(a) 201 E_(1a)E₄ E_(v)E_(vi) E_(a) 202 E_(1b)E₄ E_(v)E_(vi) E_(a) 203 E_(1a)E_(i)E₄ E_(v)E_(vi) E_(a) 204 E_(1b)E_(i)E₄ E_(v)E_(vi) E_(a) 205 E_(1a)E_(ii)E₄ E_(v)E_(vi) E_(a) 206 E_(1b)E_(ii)E₄ E_(v)E_(vi) E_(a) 207 E_(1a)E_(ii)E_(iib)E₄ E_(v)E_(vi) E_(a) 208 E_(1b)E_(ii)E_(iib)E₄ E_(v)E_(vi) E_(a) 209 E_(1a)E_(iii) E_(v)E_(vi) E_(a) 210 E_(1b)E_(iii) E_(v)E_(vi) E_(a) 211 E_(1a)E_(iii)E₄ E_(v)E_(vi) E_(a) 212 E_(1b)E_(iii)E₄ E_(v)E_(vi) E_(a) 213 E_(1a)E_(iv) E_(v)E_(vi) E_(a) 214 E_(1b)E_(iv) E_(v)E_(vi) E_(a) 215 E_(1a)E_(iv)E₄ E_(v)E_(vi) E_(a) 216 E_(1b)E_(iv)E₄ E_(v)E_(vi) E_(a) 217 E_(1a) E_(v)E_(vi) E₄* E_(a) 218 E_(1b) E_(v)E_(vi) E₄* E_(a) 219 E_(1a)E_(i) E_(v)E_(vi) E₄* E_(a) 220 E_(1b)E_(i) E_(v)E_(vi) E₄* E_(a) 221 E_(1a)E_(ii) E_(v)E_(vi) E₄* E_(a) 222 E_(1b)E_(ii) E_(v)E_(vi) E₄* E_(a) 223 E_(1a)E_(ii)E_(iib) E_(v)E_(vi) E₄* E_(a) 224 E_(1b)E_(ii)E_(iib) E_(v)E_(vi) E₄* E_(a) 225 E_(1a)E₄ E_(v)E_(vi) E₄* E_(a) 226 E_(1b)E₄ E_(v)E_(vi) E₄* E_(a) 227 E_(1a)E_(i)E₄ E_(v)E_(vi) E₄* E_(a) 228 E_(1b)E_(i)E₄ E_(v)E_(vi) E₄* E_(a) 229 E_(1a)E_(ii)E₄ E_(v)E_(vi) E₄* E_(a) 230 E_(1b)E_(ii)E₄ E_(v)E_(vi) E₄* E_(a) 231 E_(1a)E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* E_(a) 232 E_(1b)E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* E_(a) 233 E_(1a)E_(iii) E_(v)E_(vi) E₄* E_(a) 234 E_(1b)E_(iii) E_(v)E_(vi) E₄* E_(a) 235 E_(1a)E_(iii)E₄ E_(v)E_(vi) E₄* E_(a) 236 E_(1b)E_(iii)E₄ E_(v)E_(vi) E₄* E_(a) 237 E_(1a)E_(iv) E_(v)E_(vi) E₄* E_(a) 238 E_(1b)E_(iv) E_(v)E_(vi) E₄* E_(a) 239 E_(1a)E_(iv)E₄ E_(v)E_(vi) E₄* E_(a) 240 E_(1b)E_(iv)E₄ E_(v)E_(vi) E₄* E_(a) 241 E_(1a) E_(v)E_(vi) E₅ E_(a) 242 E_(1b) E_(v)E_(vi) E₅ E_(a) 243 E_(1a)E_(i) E_(v)E_(vi) E₅ E_(a) 244 E_(1b)E_(i) E_(v)E_(vi) E₅ E_(a) 245 E_(1a)E_(ii) E_(v)E_(vi) E₅ E_(a) 246 E_(1b)E_(ii) E_(v)E_(vi) E₅ E_(a) 247 E_(1a)E_(ii)E_(iib) E_(v)E_(vi) E₅ E_(a) 248 E_(1b)E_(ii)E_(iib) E_(v)E_(vi) E₅ E_(a) 249 E_(1a)E₄ E_(v)E_(vi) E₅ E_(a) 250 E_(1b)E₄ E_(v)E_(vi) E₅ E_(a) 251 E_(1a)E_(i)E₄ E_(v)E_(vi) E₅ E_(a) 252 E_(1b)E_(i)E₄ E_(v)E_(vi) E₅ E_(a) 253 E_(1a)E_(ii)E₄ E_(v)E_(vi) E₅ E_(a) 254 E_(1b)E_(ii)E₄ E_(v)E_(vi) E₅ E_(a) 255 E_(1a)E_(ii)E_(iib)E₄ E_(v)E_(vi) E₅ E_(a) 256 E_(1b)E_(ii)E_(iib)E₄ E_(v)E_(vi) E₅ E_(a) 257 E_(1a)E_(iii) E_(v)E_(vi) E₅ E_(a) 258 E_(1b)E_(iii) E_(v)E_(vi) E₅ E_(a) 259 E_(1a)E_(iii)E₄ E_(v)E_(vi) E₅ E_(a) 260 E_(1b)E_(iii)E₄ E_(v)E_(vi) E₅ E_(a) 261 E_(1a)E_(iv) E_(v)E_(vi) E₅ E_(a) 262 E_(1b)E_(iv) E_(v)E_(vi) E₅ E_(a) 263 E_(1a)E_(iv)E₄ E_(v)E_(vi) E₅ E_(a) 264 E_(1b)E_(iv)E₄ E_(v)E_(vi) E₅ E_(a) 265 E_(1a) E_(v)E_(vi) E₄*E₅ E_(a) 266 E_(1b) E_(v)E_(vi) E₄*E₅ E_(a) 267 E_(1a)E_(i) E_(v)E_(vi) E₄*E₅ E_(a) 268 E_(1b)E_(i) E_(v)E_(vi) E₄*E₅ E_(a) 269 E_(1a)E_(ii) E_(v)E_(vi) E₄*E₅ E_(a) 270 E_(1b)E_(ii) E_(v)E_(vi) E₄*E₅ E_(a) 271 E_(1a)E_(ii)E_(iib) E_(v)E_(vi) E₄*E₅ E_(a) 272 E_(1b)E_(ii)E_(iib) E_(v)E_(vi) E₄*E₅ E_(a) 273 E_(1a)E₄ E_(v)E_(vi) E₄*E₅ E_(a) 274 E_(1b)E₄ E_(v)E_(vi) E₄*E₅ E_(a) 275 E_(1a)E_(i)E₄ E_(v)E_(vi) E₄*E₅ E_(a) 276 E_(1b)E_(i)E₄ E_(v)E_(vi) E₄*E₅ E_(a) 277 E_(1a)E_(ii)E₄ E_(v)E_(vi) E₄*E₅ E_(a) 278 E_(1b)E_(ii)E₄ E_(v)E_(vi) E₄*E₅ E_(a) 279 E_(1a)E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄*E₅ E_(a) 280 E_(1b)E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄*E₅ E_(a) 281 E_(1a)E_(iii) E_(v)E_(vi) E₄*E₅ E_(a) 282 E_(1b)E_(iii) E_(v)E_(vi) E₄*E₅ E_(a) 283 E_(1a)E_(iii)E₄ E_(v)E_(vi) E₄*E₅ E_(a) 284 E_(1b)E_(iii)E₄ E_(v)E_(vi) E₄*E₅ E_(a) 285 E_(1a)E_(iv) E_(v)E_(vi) E₄*E₅ E_(a) 286 E_(1b)E_(iv) E_(v)E_(vi) E₄*E₅ E_(a) 287 E_(1a)E_(iv)E₄ E_(v)E_(vi) E₄*E₅ E_(a) 288 E_(1b)E_(iv)E₄ E_(v)E_(vi) E₄*E₅ E_(a) 289 E_(1a) AlkLE_(v)E_(vi) E_(a) 290 E_(1b) AlkLE_(v)E_(vi) E_(a) 291 E_(1a)E_(i) AlkLE_(v)E_(vi) E_(a) 292 E_(1b)E_(i) AlkLE_(v)E_(vi) E_(a) 293 E_(1a)E_(ii) AlkLE_(v)E_(vi) E_(a) 294 E_(1b)E_(ii) AlkLE_(v)E_(vi) E_(a) 295 E_(1a)E_(ii)E_(iib) AlkLE_(v)E_(vi) E_(a) 296 E_(1b)E_(ii)E_(iib) AlkLE_(v)E_(vi) E_(a) 297 E_(1a)E₄ AlkLE_(v)E_(vi) E_(a) 298 E_(1b)E₄ AlkLE_(v)E_(vi) E_(a) 299 E_(1a)E_(i)E₄ AlkLE_(v)E_(vi) E_(a) 300 E_(1b)E_(i)E₄ AlkLE_(v)E_(vi) E_(a) 301 E_(1a)E_(ii)E₄ AlkLE_(v)E_(vi) E_(a) 302 E_(1b)E_(ii)E₄ AlkLE_(v)E_(vi) E_(a) 303 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E_(a) 304 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E_(a) 305 E_(1a)E_(iii) AlkLE_(v)E_(vi) E_(a) 306 E_(1b)E_(iii) AlkLE_(v)E_(vi) E_(a) 307 E_(1a)E_(iii)E₄ AlkLE_(v)E_(vi) E_(a) 308 E_(1b)E_(iii)E₄ AlkLE_(v)E_(vi) E_(a) 309 E_(1a)E_(iv) AlkLE_(v)E_(vi) E_(a) 310 E_(1b)E_(iv) AlkLE_(v)E_(vi) E_(a) 311 E_(1a)E_(iv)E₄ AlkLE_(v)E_(vi) E_(a) 312 E_(1b)E_(iv)E₄ AlkLE_(v)E_(vi) E_(a) 313 E_(1a) AlkLE_(v)E_(vi) E₄* E_(a) 314 E_(1b) AlkLE_(v)E_(vi) E₄* E_(a) 315 E_(1a)E_(i) AlkLE_(v)E_(vi) E₄* E_(a) 316 E_(1b)E_(i) AlkLE_(v)E_(vi) E₄* E_(a) 317 E_(1a)E_(ii) AlkLE_(v)E_(vi) E₄* E_(a) 318 E_(1b)E_(ii) AlkLE_(v)E_(vi) E₄* E_(a) 319 E_(1a)E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* E_(a) 320 E_(1b)E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* E_(a) 321 E_(1a)E₄ AlkLE_(v)E_(vi) E₄* E_(a) 322 E_(1b)E₄ AlkLE_(v)E_(vi) E₄* E_(a) 323 E_(1a)E_(i)E₄ AlkLE_(v)E_(vi) E₄* E_(a) 324 E_(1b)E_(i)E₄ AlkLE_(v)E_(vi) E₄* E_(a) 325 E_(1a)E_(ii)E₄ AlkLE_(v)E_(vi) E₄* E_(a) 326 E_(1b)E_(ii)E₄ AlkLE_(v)E_(vi) E₄* E_(a) 327 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* E_(a) 328 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* E_(a) 329 E_(1a)E_(iii) AlkLE_(v)E_(vi) E₄* E_(a) 330 E_(1b)E_(iii) AlkLE_(v)E_(vi) E₄* E_(a) 331 E_(1a)E_(iii)E₄ AlkLE_(v)E_(vi) E₄* E_(a) 332 E_(1b)E_(iii)E₄ AlkLE_(v)E_(vi) E₄* E_(a) 333 E_(1a)E_(iv) AlkLE_(v)E_(vi) E₄* E_(a) 334 E_(1b)E_(iv) AlkLE_(v)E_(vi) E₄* E_(a) 335 E_(1a)E_(iv)E₄ AlkLE_(v)E_(vi) E₄* E_(a) 336 E_(1b)E_(iv)E₄ AlkLE_(v)E_(vi) E₄* E_(a) 337 E_(1a) AlkLE_(v)E_(vi) E₅ E_(a) 338 E_(1b) AlkLE_(v)E_(vi) E₅ E_(a) 339 E_(1a)E_(i) AlkLE_(v)E_(vi) E₅ E_(a) 340 E_(1b)E_(i) AlkLE_(v)E_(vi) E₅ E_(a) 341 E_(1a)E_(ii) AlkLE_(v)E_(vi) E₅ E_(a) 342 E_(1b)E_(ii) AlkLE_(v)E_(vi) E₅ E_(a) 343 E_(1a)E_(ii)E_(iib) AlkLE_(v)E_(vi) E₅ E_(a) 344 E_(1b)E_(ii)E_(iib) AlkLE_(v)E_(vi) E₅ E_(a) 345 E_(1a)E₄ AlkLE_(v)E_(vi) E₅ E_(a) 346 E_(1b)E₄ AlkLE_(v)E_(vi) E₅ E_(a) 347 E_(1a)E_(i)E₄ AlkLE_(v)E_(vi) E₅ E_(a) 348 E_(1b)E_(i)E₄ AlkLE_(v)E_(vi) E₅ E_(a) 349 E_(1a)E_(ii)E₄ AlkLE_(v)E_(vi) E₅ E_(a) 350 E_(1b)E_(ii)E₄ AlkLE_(v)E_(vi) E₅ E_(a) 351 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₅ E_(a) 352 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₅ E_(a) 353 E_(1a)E_(iii) AlkLE_(v)E_(vi) E₅ E_(a) 354 E_(1b)E_(iii) AlkLE_(v)E_(vi) E₅ E_(a) 355 E_(1a)E_(iii)E₄ AlkLE_(v)E_(vi) E₅ E_(a) 356 E_(1b)E_(iii)E₄ AlkLE_(v)E_(vi) E₅ E_(a) 357 E_(1a)E_(iv) AlkLE_(v)E_(vi) E₅ E_(a) 358 E_(1b)E_(iv) AlkLE_(v)E_(vi) E₅ E_(a) 359 E_(1a)E_(iv)E₄ AlkLE_(v)E_(vi) E₅ E_(a) 360 E_(1b)E_(iv)E₄ AlkLE_(v)E_(vi) E₅ E_(a) 361 E_(1a) AlkLE_(v)E_(vi) E₄*E₅ E_(a) 362 E_(1b) AlkLE_(v)E_(vi) E₄*E₅ E_(a) 363 E_(1a)E_(i) AlkLE_(v)E_(vi) E₄*E₅ E_(a) 364 E_(1b)E_(i) AlkLE_(v)E_(vi) E₄*E₅ E_(a) 365 E_(1a)E_(ii) AlkLE_(v)E_(vi) E₄*E₅ E_(a) 366 E_(1b)E_(ii) AlkLE_(v)E_(vi) E₄*E₅ E_(a) 367 E_(1a)E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄*E₅ E_(a) 368 E_(1b)E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄*E₅ E_(a) 369 E_(1a)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(a) 370 E_(1b)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(a) 371 E_(1a)E_(i)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(a) 372 E_(1b)E_(i)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(a) 373 E_(1a)E_(ii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(a) 374 E_(1b)E_(ii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(a) 375 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(a) 376 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(a) 377 E_(1a)E_(iii) AlkLE_(v)E_(vi) E₄*E₅ E_(a) 378 E_(1b)E_(iii) AlkLE_(v)E_(vi) E₄*E₅ E_(a) 379 E_(1a)E_(iii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(a) 380 E_(1b)E_(iii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(a) 381 E_(1a)E_(iv) AlkLE_(v)E_(vi) E₄*E₅ E_(a) 382 E_(1b)E_(iv) AlkLE_(v)E_(vi) E₄*E₅ E_(a) 383 E_(1a)E_(iv)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(a) 384 E_(1b)E_(iv)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(a) 385 E_(1a) E_(v)E_(vi) E_(b) 386 E_(1b) E_(v)E_(vi) E_(b) 387 E_(1a)E_(i) E_(v)E_(vi) E_(b) 388 E_(1b)E_(i) E_(v)E_(vi) E_(b) 389 E_(1a)E_(ii) E_(v)E_(vi) E_(b) 390 E_(1b)E_(ii) E_(v)E_(vi) E_(b) 391 E_(1a)E_(ii)E_(iib) E_(v)E_(vi) E_(b) 392 E_(1b)E_(ii)E_(iib) E_(v)E_(vi) E_(b) 393 E_(1a)E₄ E_(v)E_(vi) E_(b) 394 E_(1b)E₄ E_(v)E_(vi) E_(b) 395 E_(1a)E_(i)E₄ E_(v)E_(vi) E_(b) 396 E_(1b)E_(i)E₄ E_(v)E_(vi) E_(b) 397 E_(1a)E_(ii)E₄ E_(v)E_(vi) E_(b) 398 E_(1b)E_(ii)E₄ E_(v)E_(vi) E_(b) 399 E_(1a)E_(ii)E_(iib)E₄ E_(v)E_(vi) E_(b) 400 E_(1b)E_(ii)E_(iib)E₄ E_(v)E_(vi) E_(b) 401 E_(1a)E_(iii) E_(v)E_(vi) E_(b) 402 E_(1b)E_(iii) E_(v)E_(vi) E_(b) 403 E_(1a)E_(iii)E₄ E_(v)E_(vi) E_(b) 404 E_(1b)E_(iii)E₄ E_(v)E_(vi) E_(b) 405 E_(1a)E_(iv) E_(v)E_(vi) E_(b) 406 E_(1b)E_(iv) E_(v)E_(vi) E_(b) 407 E_(1a)E_(iv)E₄ E_(v)E_(vi) E_(b) 408 E_(1b)E_(iv)E₄ E_(v)E_(vi) E_(b) 409 E_(1a) E_(v)E_(vi) E₄* E_(b) 410 E_(1b) E_(v)E_(vi) E₄* E_(b) 411 E_(1a)E_(i) E_(v)E_(vi) E₄* E_(b) 412 E_(1b)E_(i) E_(v)E_(vi) E₄* E_(b) 413 E_(1a)E_(ii) E_(v)E_(vi) E₄* E_(b) 414 E_(1b)E_(ii) E_(v)E_(vi) E₄* E_(b) 415 E_(1a)E_(ii)E_(iib) E_(v)E_(vi) E₄* E_(b) 416 E_(1b)E_(ii)E_(iib) E_(v)E_(vi) E₄* E_(b) 417 E_(1a)E₄ E_(v)E_(vi) E₄* E_(b) 418 E_(1b)E₄ E_(v)E_(vi) E₄* E_(b) 419 E_(1a)E_(i)E₄ E_(v)E_(vi) E₄* E_(b) 420 E_(1b)E_(i)E₄ E_(v)E_(vi) E₄* E_(b) 421 E_(1a)E_(ii)E₄ E_(v)E_(vi) E₄* E_(b) 422 E_(1b)E_(ii)E₄ E_(v)E_(vi) E₄* E_(b) 423 E_(1a)E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* E_(b) 424 E_(1b)E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* E_(b) 425 E_(1a)E_(iii) E_(v)E_(vi) E₄* E_(b) 426 E_(1b)E_(iii) E_(v)E_(vi) E₄* E_(b) 427 E_(1a)E_(iii)E₄ E_(v)E_(vi) E₄* E_(b) 428 E_(1b)E_(iii)E₄ E_(v)E_(vi) E₄* E_(b) 429 E_(1a)E_(iv) E_(v)E_(vi) E₄* E_(b) 430 E_(1b)E_(iv) E_(v)E_(vi) E₄* E_(b) 431 E_(1a)E_(iv)E₄ E_(v)E_(vi) E₄* E_(b) 432 E_(1b)E_(iv)E₄ E_(v)E_(vi) E₄* E_(b) 433 E_(1a) E_(v)E_(vi) E₅ E_(b) 434 E_(1b) E_(v)E_(vi) E₅ E_(b) 435 E_(1a)E_(i) E_(v)E_(vi) E₅ E_(b) 436 E_(1b)E_(i) E_(v)E_(vi) E₅ E_(b) 437 E_(1a)E_(ii) E_(v)E_(vi) E₅ E_(b) 438 E_(1b)E_(ii) E_(v)E_(vi) E₅ E_(b) 439 E_(1a)E_(ii)E_(iib) E_(v)E_(vi) E₅ E_(b) 440 E_(1b)E_(ii)E_(iib) E_(v)E_(vi) E₅ E_(b) 441 E_(1a)E₄ E_(v)E_(vi) E₅ E_(b) 442 E_(1b)E₄ E_(v)E_(vi) E₅ E_(b) 443 E_(1a)E_(i)E₄ E_(v)E_(vi) E₅ E_(b) 444 E_(1b)E_(i)E₄ E_(v)E_(vi) E₅ E_(b) 445 E_(1a)E_(ii)E₄ E_(v)E_(vi) E₅ E_(b) 446 E_(1b)E_(ii)E₄ E_(v)E_(vi) E₅ E_(b) 447 E_(1a)E_(ii)E_(iib)E₄ E_(v)E_(vi) E₅ E_(b) 448 E_(1b)E_(ii)E_(iib)E₄ E_(v)E_(vi) E₅ E_(b) 449 E_(1a)E_(iii) E_(v)E_(vi) E₅ E_(b) 450 E_(1b)E_(iii) E_(v)E_(vi) E₅ E_(b) 451 E_(1a)E_(iii)E₄ E_(v)E_(vi) E₅ E_(b) 452 E_(1b)E_(iii)E₄ E_(v)E_(vi) E₅ E_(b) 453 E_(1a)E_(iv) E_(v)E_(vi) E₅ E_(b) 454 E_(1b)E_(iv) E_(v)E_(vi) E₅ E_(b) 455 E_(1a)E_(iv)E₄ E_(v)E_(vi) E₅ E_(b) 456 E_(1b)E_(iv)E₄ E_(v)E_(vi) E₅ E_(b) 457 E_(1a) E_(v)E_(vi) E₄*E₅ E_(b) 458 E_(1b) E_(v)E_(vi) E₄*E₅ E_(b) 459 E_(1a)E_(i) E_(v)E_(vi) E₄*E₅ E_(b) 460 E_(1b)E_(i) E_(v)E_(vi) E₄*E₅ E_(b) 461 E_(1a)E_(ii) E_(v)E_(vi) E₄*E₅ E_(b) 462 E_(1b)E_(ii) E_(v)E_(vi) E₄*E₅ E_(b) 463 E_(1a)E_(ii)E_(iib) E_(v)E_(vi) E₄*E₅ E_(b) 464 E_(1b)E_(ii)E_(iib) E_(v)E_(vi) E₄*E₅ E_(b) 465 E_(1a)E₄ E_(v)E_(vi) E₄*E₅ E_(b) 466 E_(1b)E₄ E_(v)E_(vi) E₄*E₅ E_(b) 467 E_(1a)E_(i)E₄ E_(v)E_(vi) E₄*E₅ E_(b) 468 E_(1b)E_(i)E₄ E_(v)E_(vi) E₄*E₅ E_(b) 469 E_(1a)E_(ii)E₄ E_(v)E_(vi) E₄*E₅ E_(b) 470 E_(1b)E_(ii)E₄ E_(v)E_(vi) E₄*E₅ E_(b) 471 E_(1a)E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄*E₅ E_(b) 472 E_(1b)E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄*E₅ E_(b) 473 E_(1a)E_(iii) E_(v)E_(vi) E₄*E₅ E_(b) 474 E_(1b)E_(iii) E_(v)E_(vi) E₄*E₅ E_(b) 475 E_(1a)E_(iii)E₄ E_(v)E_(vi) E₄*E₅ E_(b) 476 E_(1b)E_(iii)E₄ E_(v)E_(vi) E₄*E₅ E_(b) 477 E_(1a)E_(iv) E_(v)E_(vi) E₄*E₅ E_(b) 478 E_(1b)E_(iv) E_(v)E_(vi) E₄*E₅ E_(b) 479 E_(1a)E_(iv)E₄ E_(v)E_(vi) E₄*E₅ E_(b) 480 E_(1b)E_(iv)E₄ E_(v)E_(vi) E₄*E₅ E_(b) 481 E_(1a) AlkLE_(v)E_(vi) E_(b) 482 E_(1b) AlkLE_(v)E_(vi) E_(b) 483 E_(1a)E_(i) AlkLE_(v)E_(vi) E_(b) 484 E_(1b)E_(i) AlkLE_(v)E_(vi) E_(b) 485 E_(1a)E_(ii) AlkLE_(v)E_(vi) E_(b) 486 E_(1b)E_(ii) AlkLE_(v)E_(vi) E_(b) 487 E_(1a)E_(ii)E_(iib) AlkLE_(v)E_(vi) E_(b) 488 E_(1b)E_(ii)E_(iib) AlkLE_(v)E_(vi) E_(b) 489 E_(1a)E₄ AlkLE_(v)E_(vi) E_(b) 490 E_(1b)E₄ AlkLE_(v)E_(vi) E_(b) 491 E_(1a)E_(i)E₄ AlkLE_(v)E_(vi) E_(b) 492 E_(1b)E_(i)E₄ AlkLE_(v)E_(vi) E_(b) 493 E_(1a)E_(ii)E₄ AlkLE_(v)E_(vi) E_(b) 494 E_(1b)E_(ii)E₄ AlkLE_(v)E_(vi) E_(b) 495 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E_(b) 496 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E_(b) 497 E_(1a)E_(iii) AlkLE_(v)E_(vi) E_(b) 498 E_(1b)E_(iii) AlkLE_(v)E_(vi) E_(b) 499 E_(1a)E_(iii)E₄ AlkLE_(v)E_(vi) E_(b) 500 E_(1b)E_(iii)E₄ AlkLE_(v)E_(vi) E_(b) 501 E_(1a)E_(iv) AlkLE_(v)E_(vi) E_(b) 502 E_(1b)E_(iv) AlkLE_(v)E_(vi) E_(b) 503 E_(1a)E_(iv)E₄ AlkLE_(v)E_(vi) E_(b) 504 E_(1b)E_(iv)E₄ AlkLE_(v)E_(vi) E_(b) 505 E_(1a) AlkLE_(v)E_(vi) E₄* E_(b) 506 E_(1b) AlkLE_(v)E_(vi) E₄* E_(b) 507 E_(1a)E_(i) AlkLE_(v)E_(vi) E₄* E_(b) 508 E_(1b)E_(i) AlkLE_(v)E_(vi) E₄* E_(b) 509 E_(1a)E_(ii) AlkLE_(v)E_(vi) E₄* E_(b) 510 E_(1b)E_(ii) AlkLE_(v)E_(vi) E₄* E_(b) 511 E_(1a)E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* E_(b) 512 E_(1b)E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* E_(b) 513 E_(1a)E₄ AlkLE_(v)E_(vi) E₄* E_(b) 514 E_(1b)E₄ AlkLE_(v)E_(vi) E₄* E_(b) 515 E_(1a)E_(i)E₄ AlkLE_(v)E_(vi) E₄* E_(b) 516 E_(1b)E_(i)E₄ AlkLE_(v)E_(vi) E₄* E_(b) 517 E_(1a)E_(ii)E₄ AlkLE_(v)E_(vi) E₄* E_(b) 518 E_(1b)E_(ii)E₄ AlkLE_(v)E_(vi) E₄* E_(b) 519 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* E_(b) 520 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* E_(b) 521 E_(1a)E_(iii) AlkLE_(v)E_(vi) E₄* E_(b) 522 E_(1b)E_(iii) AlkLE_(v)E_(vi) E₄* E_(b) 523 E_(1a)E_(iii)E₄ AlkLE_(v)E_(vi) E₄* E_(b) 524 E_(1b)E_(iii)E₄ AlkLE_(v)E_(vi) E₄* E_(b) 525 E_(1a)E_(iv) AlkLE_(v)E_(vi) E₄* E_(b) 526 E_(1b)E_(iv) AlkLE_(v)E_(vi) E₄* E_(b) 527 E_(1a)E_(iv)E₄ AlkLE_(v)E_(vi) E₄* E_(b) 528 E_(1b)E_(iv)E₄ AlkLE_(v)E_(vi) E₄* E_(b) 529 E_(1a) AlkLE_(v)E_(vi) E₅ E_(b) 530 E_(1b) AlkLE_(v)E_(vi) E₅ E_(b) 531 E_(1a)E_(i) AlkLE_(v)E_(vi) E₅ E_(b) 532 E_(1b)E_(i) AlkLE_(v)E_(vi) E₅ E_(b) 533 E_(1a)E_(ii) AlkLE_(v)E_(vi) E₅ E_(b) 534 E_(1b)E_(ii) AlkLE_(v)E_(vi) E₅ E_(b) 535 E_(1a)E_(ii)E_(iib) AlkLE_(v)E_(vi) E₅ E_(b) 536 E_(1b)E_(ii)E_(iib) AlkLE_(v)E_(vi) E₅ E_(b) 537 E_(1a)E₄ AlkLE_(v)E_(vi) E₅ E_(b) 538 E_(1b)E₄ AlkLE_(v)E_(vi) E₅ E_(b) 539 E_(1a)E_(i)E₄ AlkLE_(v)E_(vi) E₅ E_(b) 540 E_(1b)E_(i)E₄ AlkLE_(v)E_(vi) E₅ E_(b) 541 E_(1a)E_(ii)E₄ AlkLE_(v)E_(vi) E₅ E_(b) 542 E_(1b)E_(ii)E₄ AlkLE_(v)E_(vi) E₅ E_(b) 543 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₅ E_(b) 544 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₅ E_(b) 545 E_(1a)E_(iii) AlkLE_(v)E_(vi) E₅ E_(b) 546 E_(1b)E_(iii) AlkLE_(v)E_(vi) E₅ E_(b) 547 E_(1a)E_(iii)E₄ AlkLE_(v)E_(vi) E₅ E_(b) 548 E_(1b)E_(iii)E₄ AlkLE_(v)E_(vi) E₅ E_(b) 549 E_(1a)E_(iv) AlkLE_(v)E_(vi) E₅ E_(b) 550 E_(1b)E_(iv) AlkLE_(v)E_(vi) E₅ E_(b) 551 E_(1a)E_(iv)E₄ AlkLE_(v)E_(vi) E₅ E_(b) 552 E_(1b)E_(iv)E₄ AlkLE_(v)E_(vi) E₅ E_(b) 553 E_(1a) AlkLE_(v)E_(vi) E₄*E₅ E_(b) 554 E_(1b) AlkLE_(v)E_(vi) E₄*E₅ E_(b) 555 E_(1a)E_(i) AlkLE_(v)E_(vi) E₄*E₅ E_(b) 556 E_(1b)E_(i) AlkLE_(v)E_(vi) E₄*E₅ E_(b) 557 E_(1a)E_(ii) AlkLE_(v)E_(vi) E₄*E₅ E_(b) 558 E_(1b)E_(ii) AlkLE_(v)E_(vi) E₄*E₅ E_(b) 559 E_(1a)E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄*E₅ E_(b) 560 E_(1b)E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄*E₅ E_(b) 561 E_(1a)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(b) 562 E_(1b)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(b) 563 E_(1a)E_(i)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(b) 564 E_(1b)E_(i)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(b) 565 E_(1a)E_(ii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(b) 566 E_(1b)E_(ii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(b) 567 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(b) 568 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(b) 569 E_(1a)E_(iii) AlkLE_(v)E_(vi) E₄*E₅ E_(b) 570 E_(1b)E_(iii) AlkLE_(v)E_(vi) E₄*E₅ E_(b) 571 E_(1a)E_(iii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(b) 572 E_(1b)E_(iii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(b) 573 E_(1a)E_(iv) AlkLE_(v)E_(vi) E₄*E₅ E_(b) 574 E_(1b)E_(iv) AlkLE_(v)E_(vi) E₄*E₅ E_(b) 575 E_(1a)E_(iv)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(b) 576 E_(1b)E_(iv)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(b) 577 E_(1a) E_(v)E_(vi) E_(d) 578 E_(1b) E_(v)E_(vi) E_(d) 579 E_(1a)E_(i) E_(v)E_(vi) E_(d) 580 E_(1b)E_(i) E_(v)E_(vi) E_(d) 581 E_(1a)E_(ii) E_(v)E_(vi) E_(d) 582 E_(1b)E_(ii) E_(v)E_(vi) E_(d) 583 E_(1a)E_(ii)E_(iib) E_(v)E_(vi) E_(d) 584 E_(1b)E_(ii)E_(iib) E_(v)E_(vi) E_(d) 585 E_(1a)E₄ E_(v)E_(vi) E_(d) 586 E_(1b)E₄ E_(v)E_(vi) E_(d) 587 E_(1a)E_(i)E₄ E_(v)E_(vi) E_(d) 588 E_(1b)E_(i)E₄ E_(v)E_(vi) E_(d) 589 E_(1a)E_(ii)E₄ E_(v)E_(vi) E_(d) 590 E_(1b)E_(ii)E₄ E_(v)E_(vi) E_(d) 591 E_(1a)E_(ii)E_(iib)E₄ E_(v)E_(vi) E_(d) 592 E_(1b)E_(ii)E_(iib)E₄ E_(v)E_(vi) E_(d) 593 E_(1a)E_(iii) E_(v)E_(vi) E_(d) 594 E_(1b)E_(iii) E_(v)E_(vi) E_(d) 595 E_(1a)E_(iii)E₄ E_(v)E_(vi) E_(d) 596 E_(1b)E_(iii)E₄ E_(v)E_(vi) E_(d) 597 E_(1a)E_(iv) E_(v)E_(vi) E_(d) 598 E_(1b)E_(iv) E_(v)E_(vi) E_(d) 599 E_(1a)E_(iv)E₄ E_(v)E_(vi) E_(d) 600 E_(1b)E_(iv)E₄ E_(v)E_(vi) E_(d) 601 E_(1a) E_(v)E_(vi) E₄* E_(d) 602 E_(1b) E_(v)E_(vi) E₄* E_(d) 603 E_(1a)E_(i) E_(v)E_(vi) E₄* E_(d) 604 E_(1b)E_(i) E_(v)E_(vi) E₄* E_(d) 605 E_(1a)E_(ii) E_(v)E_(vi) E₄* E_(d) 606 E_(1b)E_(ii) E_(v)E_(vi) E₄* E_(d) 607 E_(1a)E_(ii)E_(iib) E_(v)E_(vi) E₄* E_(d) 608 E_(1b)E_(ii)E_(iib) E_(v)E_(vi) E₄* E_(d) 609 E_(1a)E₄ E_(v)E_(vi) E₄* E_(d) 610 E_(1b)E₄ E_(v)E_(vi) E₄* E_(d) 611 E_(1a)E_(i)E₄ E_(v)E_(vi) E₄* E_(d) 612 E_(1b)E_(i)E₄ E_(v)E_(vi) E₄* E_(d) 613 E_(1a)E_(ii)E₄ E_(v)E_(vi) E₄* E_(d) 614 E_(1b)E_(ii)E₄ E_(v)E_(vi) E₄* E_(d) 615 E_(1a)E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* E_(d) 616 E_(1b)E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* E_(d) 617 E_(1a)E_(iii) E_(v)E_(vi) E₄* E_(d) 618 E_(1b)E_(iii) E_(v)E_(vi) E₄* E_(d) 619 E_(1a)E_(iii)E₄ E_(v)E_(vi) E₄* E_(d) 620 E_(1b)E_(iii)E₄ E_(v)E_(vi) E₄* E_(d) 621 E_(1a)E_(iv) E_(v)E_(vi) E₄* E_(d) 622 E_(1b)E_(iv) E_(v)E_(vi) E₄* E_(d) 623 E_(1a)E_(iv)E₄ E_(v)E_(vi) E₄* E_(d) 624 E_(1b)E_(iv)E₄ E_(v)E_(vi) E₄* E_(d) 625 E_(1a) E_(v)E_(vi) E₅ E_(d) 626 E_(1b) E_(v)E_(vi) E₅ E_(d) 627 E_(1a)E_(i) E_(v)E_(vi) E₅ E_(d) 628 E_(1b)E_(i) E_(v)E_(vi) E₅ E_(d) 629 E_(1a)E_(ii) E_(v)E_(vi) E₅ E_(d) 630 E_(1b)E_(ii) E_(v)E_(vi) E₅ E_(d) 631 E_(1a)E_(ii)E_(iib) E_(v)E_(vi) E₅ E_(d) 632 E_(1b)E_(ii)E_(iib) E_(v)E_(vi) E₅ E_(d) 633 E_(1a)E₄ E_(v)E_(vi) E₅ E_(d) 634 E_(1b)E₄ E_(v)E_(vi) E₅ E_(d) 635 E_(1a)E_(i)E₄ E_(v)E_(vi) E₅ E_(d) 636 E_(1b)E_(i)E₄ E_(v)E_(vi) E₅ E_(d) 637 E_(1a)E_(ii)E₄ E_(v)E_(vi) E₅ E_(d) 638 E_(1b)E_(ii)E₄ E_(v)E_(vi) E₅ E_(d) 639 E_(1a)E_(ii)E_(iib)E₄ E_(v)E_(vi) E₅ E_(d) 640 E_(1b)E_(ii)E_(iib)E₄ E_(v)E_(vi) E₅ E_(d) 641 E_(1a)E_(iii) E_(v)E_(vi) E₅ E_(d) 642 E_(1b)E_(iii) E_(v)E_(vi) E₅ E_(d) 643 E_(1a)E_(iii)E₄ E_(v)E_(vi) E₅ E_(d) 644 E_(1b)E_(iii)E₄ E_(v)E_(vi) E₅ E_(d) 645 E_(1a)E_(iv) E_(v)E_(vi) E₅ E_(d) 646 E_(1b)E_(iv) E_(v)E_(vi) E₅ E_(d) 647 E_(1a)E_(iv)E₄ E_(v)E_(vi) E₅ E_(d) 648 E_(1b)E_(iv)E₄ E_(v)E_(vi) E₅ E_(d) 649 E_(1a) E_(v)E_(vi) E₄*E₅ E_(d) 650 E_(1b) E_(v)E_(vi) E₄*E₅ E_(d) 651 E_(1a)E_(i) E_(v)E_(vi) E₄*E₅ E_(d) 652 E_(1b)E_(i) E_(v)E_(vi) E₄*E₅ E_(d) 653 E_(1a)E_(ii) E_(v)E_(vi) E₄*E₅ E_(d) 654 E_(1b)E_(ii) E_(v)E_(vi) E₄*E₅ E_(d) 655 E_(1a)E_(ii)E_(iib) E_(v)E_(vi) E₄*E₅ E_(d) 656 E_(1b)E_(ii)E_(iib) E_(v)E_(vi) E₄*E₅ E_(d) 657 E_(1a)E₄ E_(v)E_(vi) E₄*E₅ E_(d) 658 E_(1b)E₄ E_(v)E_(vi) E₄*E₅ E_(d) 659 E_(1a)E_(i)E₄ E_(v)E_(vi) E₄*E₅ E_(d) 660 E_(1b)E_(i)E₄ E_(v)E_(vi) E₄*E₅ E_(d) 661 E_(1a)E_(ii)E₄ E_(v)E_(vi) E₄*E₅ E_(d) 662 E_(1b)E_(ii)E₄ E_(v)E_(vi) E₄*E₅ E_(d) 663 E_(1a)E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄*E₅ E_(d) 664 E_(1b)E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄*E₅ E_(d) 665 E_(1a)E_(iii) E_(v)E_(vi) E₄*E₅ E_(d) 666 E_(1b)E_(iii) E_(v)E_(vi) E₄*E₅ E_(d) 667 E_(1a)E_(iii)E₄ E_(v)E_(vi) E₄*E₅ E_(d) 668 E_(1b)E_(iii)E₄ E_(v)E_(vi) E₄*E₅ E_(d) 669 E_(1a)E_(iv) E_(v)E_(vi) E₄*E₅ E_(d) 670 E_(1b)E_(iv) E_(v)E_(vi) E₄*E₅ E_(d) 671 E_(1a)E_(iv)E₄ E_(v)E_(vi) E₄*E₅ E_(d) 672 E_(1b)E_(iv)E₄ E_(v)E_(vi) E₄*E₅ E_(d) 673 E_(1a) AlkLE_(v)E_(vi) E_(d) 674 E_(1b) AlkLE_(v)E_(vi) E_(d) 675 E_(1a)E_(i) AlkLE_(v)E_(vi) E_(d) 676 E_(1b)E_(i) AlkLE_(v)E_(vi) E_(d) 677 E_(1a)E_(ii) AlkLE_(v)E_(vi) E_(d) 678 E_(1b)E_(ii) AlkLE_(v)E_(vi) E_(d) 679 E_(1a)E_(ii)E_(iib) AlkLE_(v)E_(vi) E_(d) 680 E_(1b)E_(ii)E_(iib) AlkLE_(v)E_(vi) E_(d) 681 E_(1a)E₄ AlkLE_(v)E_(vi) E_(d) 682 E_(1b)E₄ AlkLE_(v)E_(vi) E_(d) 683 E_(1a)E_(i)E₄ AlkLE_(v)E_(vi) E_(d) 684 E_(1b)E_(i)E₄ AlkLE_(v)E_(vi) E_(d) 685 E_(1a)E_(ii)E₄ AlkLE_(v)E_(vi) E_(d) 686 E_(1b)E_(ii)E₄ AlkLE_(v)E_(vi) E_(d) 687 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E_(d) 688 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E_(d) 689 E_(1a)E_(iii) AlkLE_(v)E_(vi) E_(d) 690 E_(1b)E_(iii) AlkLE_(v)E_(vi) E_(d) 691 E_(1a)E_(iii)E₄ AlkLE_(v)E_(vi) E_(d) 692 E_(1b)E_(iii)E₄ AlkLE_(v)E_(vi) E_(d) 693 E_(1a)E_(iv) AlkLE_(v)E_(vi) E_(d) 694 E_(1b)E_(iv) AlkLE_(v)E_(vi) E_(d) 695 E_(1a)E_(iv)E₄ AlkLE_(v)E_(vi) E_(d) 696 E_(1b)E_(iv)E₄ AlkLE_(v)E_(vi) E_(d) 697 E_(1a) AlkLE_(v)E_(vi) E₄* E_(d) 698 E_(1b) AlkLE_(v)E_(vi) E₄* E_(d) 699 E_(1a)E_(i) AlkLE_(v)E_(vi) E₄* E_(d) 700 E_(1b)E_(i) AlkLE_(v)E_(vi) E₄* E_(d) 701 E_(1a)E_(ii) AlkLE_(v)E_(vi) E₄* E_(d) 702 E_(1b)E_(ii) AlkLE_(v)E_(vi) E₄* E_(d) 703 E_(1a)E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* E_(d) 704 E_(1b)E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* E_(d) 705 E_(1a)E₄ AlkLE_(v)E_(vi) E₄* E_(d) 706 E_(1b)E₄ AlkLE_(v)E_(vi) E₄* E_(d) 707 E_(1a)E_(i)E₄ AlkLE_(v)E_(vi) E₄* E_(d) 708 E_(1b)E_(i)E₄ AlkLE_(v)E_(vi) E₄* E_(d) 709 E_(1a)E_(ii)E₄ AlkLE_(v)E_(vi) E₄* E_(d) 710 E_(1b)E_(ii)E₄ AlkLE_(v)E_(vi) E₄* E_(d) 711 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* E_(d) 712 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* E_(d) 713 E_(1a)E_(iii) AlkLE_(v)E_(vi) E₄* E_(d) 714 E_(1b)E_(iii) AlkLE_(v)E_(vi) E₄* E_(d) 715 E_(1a)E_(iii)E₄ AlkLE_(v)E_(vi) E₄* E_(d) 716 E_(1b)E_(iii)E₄ AlkLE_(v)E_(vi) E₄* E_(d) 717 E_(1a)E_(iv) AlkLE_(v)E_(vi) E₄* E_(d) 718 E_(1b)E_(iv) AlkLE_(v)E_(vi) E₄* E_(d) 719 E_(1a)E_(iv)E₄ AlkLE_(v)E_(vi) E₄* E_(d) 720 E_(1b)E_(iv)E₄ AlkLE_(v)E_(vi) E₄* E_(d) 721 E_(1a) AlkLE_(v)E_(vi) E₅ E_(d) 722 E_(1b) AlkLE_(v)E_(vi) E₅ E_(d) 723 E_(1a)E_(i) AlkLE_(v)E_(vi) E₅ E_(d) 724 E_(1b)E_(i) AlkLE_(v)E_(vi) E₅ E_(d) 725 E_(1a)E_(ii) AlkLE_(v)E_(vi) E₅ E_(d) 726 E_(1b)E_(ii) AlkLE_(v)E_(vi) E₅ E_(d) 727 E_(1a)E_(ii)E_(iib) AlkLE_(v)E_(vi) E₅ E_(d) 728 E_(1b)E_(ii)E_(iib) AlkLE_(v)E_(vi) E₅ E_(d) 729 E_(1a)E₄ AlkLE_(v)E_(vi) E₅ E_(d) 730 E_(1b)E₄ AlkLE_(v)E_(vi) E₅ E_(d) 731 E_(1a)E_(i)E₄ AlkLE_(v)E_(vi) E₅ E_(d) 732 E_(1b)E_(i)E₄ AlkLE_(v)E_(vi) E₅ E_(d) 733 E_(1a)E_(ii)E₄ AlkLE_(v)E_(vi) E₅ E_(d) 734 E_(1b)E_(ii)E₄ AlkLE_(v)E_(vi) E₅ E_(d) 735 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₅ E_(d) 736 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₅ E_(d) 737 E_(1a)E_(iii) AlkLE_(v)E_(vi) E₅ E_(d) 738 E_(1b)E_(iii) AlkLE_(v)E_(vi) E₅ E_(d) 739 E_(1a)E_(iii)E₄ AlkLE_(v)E_(vi) E₅ E_(d) 740 E_(1b)E_(iii)E₄ AlkLE_(v)E_(vi) E₅ E_(d) 741 E_(1a)E_(iv) AlkLE_(v)E_(vi) E₅ E_(d) 742 E_(1b)E_(iv) AlkLE_(v)E_(vi) E₅ E_(d) 743 E_(1a)E_(iv)E₄ AlkLE_(v)E_(vi) E₅ E_(d) 744 E_(1b)E_(iv)E₄ AlkLE_(v)E_(vi) E₅ E_(d) 745 E_(1a) AlkLE_(v)E_(vi) E₄*E₅ E_(d) 746 E_(1b) AlkLE_(v)E_(vi) E₄*E₅ E_(d) 747 E_(1a)E_(i) AlkLE_(v)E_(vi) E₄*E₅ E_(d) 748 E_(1b)E_(i) AlkLE_(v)E_(vi) E₄*E₅ E_(d) 749 E_(1a)E_(ii) AlkLE_(v)E_(vi) E₄*E₅ E_(d) 750 E_(1b)E_(ii) AlkLE_(v)E_(vi) E₄*E₅ E_(d) 751 E_(1a)E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄*E₅ E_(d) 752 E_(1b)E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄*E₅ E_(d) 753 E_(1a)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(d) 754 E_(1b)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(d) 755 E_(1a)E_(i)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(d) 756 E_(1b)E_(i)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(d) 757 E_(1a)E_(ii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(d) 758 E_(1b)E_(ii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(d) 759 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(d) 760 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(d) 761 E_(1a)E_(iii) AlkLE_(v)E_(vi) E₄*E₅ E_(d) 762 E_(1b)E_(iii) AlkLE_(v)E_(vi) E₄*E₅ E_(d) 763 E_(1a)E_(iii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(d) 764 E_(1b)E_(iii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(d) 765 E_(1a)E_(iv) AlkLE_(v)E_(vi) E₄*E₅ E_(d) 766 E_(1b)E_(iv) AlkLE_(v)E_(vi) E₄*E₅ E_(d) 767 E_(1a)E_(iv)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(d) 768 E_(1b)E_(iv)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(d) 769 E_(1a) E_(v)E_(vi) E_(e) 770 E_(1b) E_(v)E_(vi) E_(e) 771 E_(1a)E_(i) E_(v)E_(vi) E_(e) 772 E_(1b)E_(i) E_(v)E_(vi) E_(e) 773 E_(1a)E_(ii) E_(v)E_(vi) E_(e) 774 E_(1b)E_(ii) E_(v)E_(vi) E_(e) 775 E_(1a)E_(ii)E_(iib) E_(v)E_(vi) E_(e) 776 E_(1b)E_(ii)E_(iib) E_(v)E_(vi) E_(e) 777 E_(1a)E₄ E_(v)E_(vi) E_(e) 778 E_(1b)E₄ E_(v)E_(vi) E_(e) 779 E_(1a)E_(i)E₄ E_(v)E_(vi) E_(e) 780 E_(1b)E_(i)E₄ E_(v)E_(vi) E_(e) 781 E_(1a)E_(ii)E₄ E_(v)E_(vi) E_(e) 782 E_(1b)E_(ii)E₄ E_(v)E_(vi) E_(e) 783 E_(1a)E_(ii)E_(iib)E₄ E_(v)E_(vi) E_(e) 784 E_(1b)E_(ii)E_(iib)E₄ E_(v)E_(vi) E_(e) 785 E_(1a)E_(iii) E_(v)E_(vi) E_(e) 786 E_(1b)E_(iii) E_(v)E_(vi) E_(e) 787 E_(1a)E_(iii)E₄ E_(v)E_(vi) E_(e) 788 E_(1b)E_(iii)E₄ E_(v)E_(vi) E_(e) 789 E_(1a)E_(iv) E_(v)E_(vi) E_(e) 790 E_(1b)E_(iv) E_(v)E_(vi) E_(e) 791 E_(1a)E_(iv)E₄ E_(v)E_(vi) E_(e) 792 E_(1b)E_(iv)E₄ E_(v)E_(vi) E_(e) 793 E_(1a) E_(v)E_(vi) E₄* E_(e) 794 E_(1b) E_(v)E_(vi) E₄* E_(e) 795 E_(1a)E_(i) E_(v)E_(vi) E₄* E_(e) 796 E_(1b)E_(i) E_(v)E_(vi) E₄* E_(e) 797 E_(1a)E_(ii) E_(v)E_(vi) E₄* E_(e) 798 E_(1b)E_(ii) E_(v)E_(vi) E₄* E_(e) 799 E_(1a)E_(ii)E_(iib) E_(v)E_(vi) E₄* E_(e) 800 E_(1b)E_(ii)E_(iib) E_(v)E_(vi) E₄* E_(e) 801 E_(1a)E₄ E_(v)E_(vi) E₄* E_(e) 802 E_(1b)E₄ E_(v)E_(vi) E₄* E_(e) 803 E_(1a)E_(i)E₄ E_(v)E_(vi) E₄* E_(e) 804 E_(1b)E_(i)E₄ E_(v)E_(vi) E₄* E_(e) 805 E_(1a)E_(ii)E₄ E_(v)E_(vi) E₄* E_(e) 806 E_(1b)E_(ii)E₄ E_(v)E_(vi) E₄* E_(e) 807 E_(1a)E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* E_(e) 808 E_(1b)E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* E_(e) 809 E_(1a)E_(iii) E_(v)E_(vi) E₄* E_(e) 810 E_(1b)E_(iii) E_(v)E_(vi) E₄* E_(e) 811 E_(1a)E_(iii)E₄ E_(v)E_(vi) E₄* E_(e) 812 E_(1b)E_(iii)E₄ E_(v)E_(vi) E₄* E_(e) 813 E_(1a)E_(iv) E_(v)E_(vi) E₄* E_(e) 814 E_(1b)E_(iv) E_(v)E_(vi) E₄* E_(e) 815 E_(1a)E_(iv)E₄ E_(v)E_(vi) E₄* E_(e) 816 E_(1b)E_(iv)E₄ E_(v)E_(vi) E₄* E_(e) 817 E_(1a) E_(v)E_(vi) E₅ E_(e) 818 E_(1b) E_(v)E_(vi) E₅ E_(e) 819 E_(1a)E_(i) E_(v)E_(vi) E₅ E_(e) 820 E_(1b)E_(i) E_(v)E_(vi) E₅ E_(e) 821 E_(1a)E_(ii) E_(v)E_(vi) E₅ E_(e) 822 E_(1b)E_(ii) E_(v)E_(vi) E₅ E_(e) 823 E_(1a)E_(ii)E_(iib) E_(v)E_(vi) E₅ E_(e) 824 E_(1b)E_(ii)E_(iib) E_(v)E_(vi) E₅ E_(e) 825 E_(1a)E₄ E_(v)E_(vi) E₅ E_(e) 826 E_(1b)E₄ E_(v)E_(vi) E₅ E_(e) 827 E_(1a)E_(i)E₄ E_(v)E_(vi) E₅ E_(e) 828 E_(1b)E_(i)E₄ E_(v)E_(vi) E₅ E_(e) 829 E_(1a)E_(ii)E₄ E_(v)E_(vi) E₅ E_(e) 830 E_(1b)E_(ii)E₄ E_(v)E_(vi) E₅ E_(e) 831 E_(1a)E_(ii)E_(iib)E₄ E_(v)E_(vi) E₅ E_(e) 832 E_(1b)E_(ii)E_(iib)E₄ E_(v)E_(vi) E₅ E_(e) 833 E_(1a)E_(iii) E_(v)E_(vi) E₅ E_(e) 834 E_(1b)E_(iii) E_(v)E_(vi) E₅ E_(e) 835 E_(1a)E_(iii)E₄ E_(v)E_(vi) E₅ E_(e) 836 E_(1b)E_(iii)E₄ E_(v)E_(vi) E₅ E_(e) 837 E_(1a)E_(iv) E_(v)E_(vi) E₅ E_(e) 838 E_(1b)E_(iv) E_(v)E_(vi) E₅ E_(e) 839 E_(1a)E_(iv)E₄ E_(v)E_(vi) E₅ E_(e) 840 E_(1b)E_(iv)E₄ E_(v)E_(vi) E₅ E_(e) 841 E_(1a) E_(v)E_(vi) E₄*E₅ E_(e) 842 E_(1b) E_(v)E_(vi) E₄*E₅ E_(e) 843 E_(1a)E_(i) E_(v)E_(vi) E₄*E₅ E_(e) 844 E_(1b)E_(i) E_(v)E_(vi) E₄*E₅ E_(e) 845 E_(1a)E_(ii) E_(v)E_(vi) E₄*E₅ E_(e) 846 E_(1b)E_(ii) E_(v)E_(vi) E₄*E₅ E_(e) 847 E_(1a)E_(ii)E_(iib) E_(v)E_(vi) E₄*E₅ E_(e) 848 E_(1b)E_(ii)E_(iib) E_(v)E_(vi) E₄*E₅ E_(e) 849 E_(1a)E₄ E_(v)E_(vi) E₄*E₅ E_(e) 850 E_(1b)E₄ E_(v)E_(vi) E₄*E₅ E_(e) 851 E_(1a)E_(i)E₄ E_(v)E_(vi) E₄*E₅ E_(e) 852 E_(1b)E_(i)E₄ E_(v)E_(vi) E₄*E₅ E_(e) 853 E_(1a)E_(ii)E₄ E_(v)E_(vi) E₄*E₅ E_(e) 854 E_(1b)E_(ii)E₄ E_(v)E_(vi) E₄*E₅ E_(e) 855 E_(1a)E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄*E₅ E_(e) 856 E_(1b)E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄*E₅ E_(e) 857 E_(1a)E_(iii) E_(v)E_(vi) E₄*E₅ E_(e) 858 E_(1b)E_(iii) E_(v)E_(vi) E₄*E₅ E_(e) 859 E_(1a)E_(iii)E₄ E_(v)E_(vi) E₄*E₅ E_(e) 860 E_(1b)E_(iii)E₄ E_(v)E_(vi) E₄*E₅ E_(e) 861 E_(1a)E_(iv) E_(v)E_(vi) E₄*E₅ E_(e) 862 E_(1b)E_(iv) E_(v)E_(vi) E₄*E₅ E_(e) 863 E_(1a)E_(iv)E₄ E_(v)E_(vi) E₄*E₅ E_(e) 864 E_(1b)E_(iv)E₄ E_(v)E_(vi) E₄*E₅ E_(e) 865 E_(1a) AlkLE_(v)E_(vi) E_(e) 866 E_(1b) AlkLE_(v)E_(vi) E_(e) 867 E_(1a)E_(i) AlkLE_(v)E_(vi) E_(e) 868 E_(1b)E_(i) AlkLE_(v)E_(vi) E_(e) 869 E_(1a)E_(ii) AlkLE_(v)E_(vi) E_(e) 870 E_(1b)E_(ii) AlkLE_(v)E_(vi) E_(e) 871 E_(1a)E_(ii)E_(iib) AlkLE_(v)E_(vi) E_(e) 872 E_(1b)E_(ii)E_(iib) AlkLE_(v)E_(vi) E_(e) 873 E_(1a)E₄ AlkLE_(v)E_(vi) E_(e) 874 E_(1b)E₄ AlkLE_(v)E_(vi) E_(e) 875 E_(1a)E_(i)E₄ AlkLE_(v)E_(vi) E_(e) 876 E_(1b)E_(i)E₄ AlkLE_(v)E_(vi) E_(e) 877 E_(1a)E_(ii)E₄ AlkLE_(v)E_(vi) E_(e) 878 E_(1b)E_(ii)E₄ AlkLE_(v)E_(vi) E_(e) 879 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E_(e) 880 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E_(e) 881 E_(1a)E_(iii) AlkLE_(v)E_(vi) E_(e) 882 E_(1b)E_(iii) AlkLE_(v)E_(vi) E_(e) 883 E_(1a)E_(iii)E₄ AlkLE_(v)E_(vi) E_(e) 884 E_(1b)E_(iii)E₄ AlkLE_(v)E_(vi) E_(e) 885 E_(1a)E_(iv) AlkLE_(v)E_(vi) E_(e) 886 E_(1b)E_(iv) AlkLE_(v)E_(vi) E_(e) 887 E_(1a)E_(iv)E₄ AlkLE_(v)E_(vi) E_(e) 888 E_(1b)E_(iv)E₄ AlkLE_(v)E_(vi) E_(e) 889 E_(1a) AlkLE_(v)E_(vi) E₄* E_(e) 890 E_(1b) AlkLE_(v)E_(vi) E₄* E_(e) 891 E_(1a)E_(i) AlkLE_(v)E_(vi) E₄* E_(e) 892 E_(1b)E_(i) AlkLE_(v)E_(vi) E₄* E_(e) 893 E_(1a)E_(ii) AlkLE_(v)E_(vi) E₄* E_(e) 894 E_(1b)E_(ii) AlkLE_(v)E_(vi) E₄* E_(e) 895 E_(1a)E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* E_(e) 896 E_(1b)E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* E_(e) 897 E_(1a)E₄ AlkLE_(v)E_(vi) E₄* E_(e) 898 E_(1b)E₄ AlkLE_(v)E_(vi) E₄* E_(e) 899 E_(1a)E_(i)E₄ AlkLE_(v)E_(vi) E₄* E_(e) 900 E_(1b)E_(i)E₄ AlkLE_(v)E_(vi) E₄* E_(e) 901 E_(1a)E_(ii)E₄ AlkLE_(v)E_(vi) E₄* E_(e) 902 E_(1b)E_(ii)E₄ AlkLE_(v)E_(vi) E₄* E_(e) 903 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* E_(e) 904 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* E_(e) 905 E_(1a)E_(iii) AlkLE_(v)E_(vi) E₄* E_(e) 906 E_(1b)E_(iii) AlkLE_(v)E_(vi) E₄* E_(e) 907 E_(1a)E_(iii)E₄ AlkLE_(v)E_(vi) E₄* E_(e) 908 E_(1b)E_(iii)E₄ AlkLE_(v)E_(vi) E₄* E_(e) 909 E_(1a)E_(iv) AlkLE_(v)E_(vi) E₄* E_(e) 910 E_(1b)E_(iv) AlkLE_(v)E_(vi) E₄* E_(e) 911 E_(1a)E_(iv)E₄ AlkLE_(v)E_(vi) E₄* E_(e) 912 E_(1b)E_(iv)E₄ AlkLE_(v)E_(vi) E₄* E_(e) 913 E_(1a) AlkLE_(v)E_(vi) E₅ E_(e) 914 E_(1b) AlkLE_(v)E_(vi) E₅ E_(e) 915 E_(1a)E_(i) AlkLE_(v)E_(vi) E₅ E_(e) 916 E_(1b)E_(i) AlkLE_(v)E_(vi) E₅ E_(e) 917 E_(1a)E_(ii) AlkLE_(v)E_(vi) E₅ E_(e) 918 E_(1b)E_(ii) AlkLE_(v)E_(vi) E₅ E_(e) 919 E_(1a)E_(ii)E_(iib) AlkLE_(v)E_(vi) E₅ E_(e) 920 E_(1b)E_(ii)E_(iib) AlkLE_(v)E_(vi) E₅ E_(e) 921 E_(1a)E₄ AlkLE_(v)E_(vi) E₅ E_(e) 922 E_(1b)E₄ AlkLE_(v)E_(vi) E₅ E_(e) 923 E_(1a)E_(i)E₄ AlkLE_(v)E_(vi) E₅ E_(e) 924 E_(1b)E_(i)E₄ AlkLE_(v)E_(vi) E₅ E_(e) 925 E_(1a)E_(ii)E₄ AlkLE_(v)E_(vi) E₅ E_(e) 926 E_(1b)E_(ii)E₄ AlkLE_(v)E_(vi) E₅ E_(e) 927 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₅ E_(e) 928 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₅ E_(e) 929 E_(1a)E_(iii) AlkLE_(v)E_(vi) E₅ E_(e) 930 E_(1b)E_(iii) AlkLE_(v)E_(vi) E₅ E_(e) 931 E_(1a)E_(iii)E₄ AlkLE_(v)E_(vi) E₅ E_(e) 932 E_(1b)E_(iii)E₄ AlkLE_(v)E_(vi) E₅ E_(e) 933 E_(1a)E_(iv) AlkLE_(v)E_(vi) E₅ E_(e) 934 E_(1b)E_(iv) AlkLE_(v)E_(vi) E₅ E_(e) 935 E_(1a)E_(iv)E₄ AlkLE_(v)E_(vi) E₅ E_(e) 936 E_(1b)E_(iv)E₄ AlkLE_(v)E_(vi) E₅ E_(e) 937 E_(1a) AlkLE_(v)E_(vi) E₄*E₅ E_(e) 938 E_(1b) AlkLE_(v)E_(vi) E₄*E₅ E_(e) 939 E_(1a)E_(i) AlkLE_(v)E_(vi) E₄*E₅ E_(e) 940 E_(1b)E_(i) AlkLE_(v)E_(vi) E₄*E₅ E_(e) 941 E_(1a)E_(ii) AlkLE_(v)E_(vi) E₄*E₅ E_(e) 942 E_(1b)E_(ii) AlkLE_(v)E_(vi) E₄*E₅ E_(e) 943 E_(1a)E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄*E₅ E_(e) 944 E_(1b)E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄*E₅ E_(e) 945 E_(1a)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(e) 946 E_(1b)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(e) 947 E_(1a)E_(i)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(e) 948 E_(1b)E_(i)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(e) 949 E_(1a)E_(ii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(e) 950 E_(1b)E_(ii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(e) 951 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(e) 952 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(e) 953 E_(1a)E_(iii) AlkLE_(v)E_(vi) E₄*E₅ E_(e) 954 E_(1b)E_(iii) AlkLE_(v)E_(vi) E₄*E₅ E_(e) 955 E_(1a)E_(iii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(e) 956 E_(1b)E_(iii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(e) 957 E_(1a)E_(iv) AlkLE_(v)E_(vi) E₄*E₅ E_(e) 958 E_(1b)E_(iv) AlkLE_(v)E_(vi) E₄*E₅ E_(e) 959 E_(1a)E_(iv)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(e) 960 E_(1b)E_(iv)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(e) 961 E_(1a) E_(v)E_(vi) E_(f) 962 E_(1b) E_(v)E_(vi) E_(f) 963 E_(1a)E_(i) E_(v)E_(vi) E_(f) 964 E_(1b)E_(i) E_(v)E_(vi) E_(f) 965 E_(1a)E_(ii) E_(v)E_(vi) E_(f) 966 E_(1b)E_(ii) E_(v)E_(vi) E_(f) 967 E_(1a)E_(ii)E_(iib) E_(v)E_(vi) E_(f) 968 E_(1b)E_(ii)E_(iib) E_(v)E_(vi) E_(f) 969 E_(1a)E₄ E_(v)E_(vi) E_(f) 970 E_(1b)E₄ E_(v)E_(vi) E_(f) 971 E_(1a)E_(i)E₄ E_(v)E_(vi) E_(f) 972 E_(1b)E_(i)E₄ E_(v)E_(vi) E_(f) 973 E_(1a)E_(ii)E₄ E_(v)E_(vi) E_(f) 974 E_(1b)E_(ii)E₄ E_(v)E_(vi) E_(f) 975 E_(1a)E_(ii)E_(iib)E₄ E_(v)E_(vi) E_(f) 976 E_(1b)E_(ii)E_(iib)E₄ E_(v)E_(vi) E_(f) 977 E_(1a)E_(iii) E_(v)E_(vi) E_(f) 978 E_(1b)E_(iii) E_(v)E_(vi) E_(f) 979 E_(1a)E_(iii)E₄ E_(v)E_(vi) E_(f) 980 E_(1b)E_(iii)E₄ E_(v)E_(vi) E_(f) 981 E_(1a)E_(iv) E_(v)E_(vi) E_(f) 982 E_(1b)E_(iv) E_(v)E_(vi) E_(f) 983 E_(1a)E_(iv)E₄ E_(v)E_(vi) E_(f) 984 E_(1b)E_(iv)E₄ E_(v)E_(vi) E_(f) 985 E_(1a) E_(v)E_(vi) E₄* E_(f) 986 E_(1b) E_(v)E_(vi) E₄* E_(f) 987 E_(1a)E_(i) E_(v)E_(vi) E₄* E_(f) 988 E_(1b)E_(i) E_(v)E_(vi) E₄* E_(f) 989 E_(1a)E_(ii) E_(v)E_(vi) E₄* E_(f) 990 E_(1b)E_(ii) E_(v)E_(vi) E₄* E_(f) 991 E_(1a)E_(ii)E_(iib) E_(v)E_(vi) E₄* E_(f) 992 E_(1b)E_(ii)E_(iib) E_(v)E_(vi) E₄* E_(f) 993 E_(1a)E₄ E_(v)E_(vi) E₄* E_(f) 994 E_(1b)E₄ E_(v)E_(vi) E₄* E_(f) 995 E_(1a)E_(i)E₄ E_(v)E_(vi) E₄* E_(f) 996 E_(1b)E_(i)E₄ E_(v)E_(vi) E₄* E_(f) 997 E_(1a)E_(ii)E₄ E_(v)E_(vi) E₄* E_(f) 998 E_(1b)E_(ii)E₄ E_(v)E_(vi) E₄* E_(f) 999 E_(1a)E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* E_(f) 1000 E_(1b)E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* E_(f) 1001 E_(1a)E_(iii) E_(v)E_(vi) E₄* E_(f) 1002 E_(1b)E_(iii) E_(v)E_(vi) E₄* E_(f) 1003 E_(1a)E_(iii)E₄ E_(v)E_(vi) E₄* E_(f) 1004 E_(1b)E_(iii)E₄ E_(v)E_(vi) E₄* E_(f) 1005 E_(1a)E_(iv) E_(v)E_(vi) E₄* E_(f) 1006 E_(1b)E_(iv) E_(v)E_(vi) E₄* E_(f) 1007 E_(1a)E_(iv)E₄ E_(v)E_(vi) E₄* E_(f) 1008 E_(1b)E_(iv)E₄ E_(v)E_(vi) E₄* E_(f) 1009 E_(1a) E_(v)E_(vi) E₅ E_(f) 1010 E_(1b) E_(v)E_(vi) E₅ E_(f) 1011 E_(1a)E_(i) E_(v)E_(vi) E₅ E_(f) 1012 E_(1b)E_(i) E_(v)E_(vi) E₅ E_(f) 1013 E_(1a)E_(ii) E_(v)E_(vi) E₅ E_(f) 1014 E_(1b)E_(ii) E_(v)E_(vi) E₅ E_(f) 1015 E_(1a)E_(ii)E_(iib) E_(v)E_(vi) E₅ E_(f) 1016 E_(1b)E_(ii)E_(iib) E_(v)E_(vi) E₅ E_(f) 1017 E_(1a)E₄ E_(v)E_(vi) E₅ E_(f) 1018 E_(1b)E₄ E_(v)E_(vi) E₅ E_(f) 1019 E_(1a)E_(i)E₄ E_(v)E_(vi) E₅ E_(f) 1020 E_(1b)E_(i)E₄ E_(v)E_(vi) E₅ E_(f) 1021 E_(1a)E_(ii)E₄ E_(v)E_(vi) E₅ E_(f) 1022 E_(1b)E_(ii)E₄ E_(v)E_(vi) E₅ E_(f) 1023 E_(1a)E_(ii)E_(iib)E₄ E_(v)E_(vi) E₅ E_(f) 1024 E_(1b)E_(ii)E_(iib)E₄ E_(v)E_(vi) E₅ E_(f) 1025 E_(1a)E_(iii) E_(v)E_(vi) E₅ E_(f) 1026 E_(1b)E_(iii) E_(v)E_(vi) E₅ E_(f) 1027 E_(1a)E_(iii)E₄ E_(v)E_(vi) E₅ E_(f) 1028 E_(1b)E_(iii)E₄ E_(v)E_(vi) E₅ E_(f) 1029 E_(1a)E_(iv) E_(v)E_(vi) E₅ E_(f) 1030 E_(1b)E_(iv) E_(v)E_(vi) E₅ E_(f) 1031 E_(1a)E_(iv)E₄ E_(v)E_(vi) E₅ E_(f) 1032 E_(1b)E_(iv)E₄ E_(v)E_(vi) E₅ E_(f) 1033 E_(1a) E_(v)E_(vi) E₄*E₅ E_(f) 1034 E_(1b) E_(v)E_(vi) E₄*E₅ E_(f) 1035 E_(1a)E_(i) E_(v)E_(vi) E₄*E₅ E_(f) 1036 E_(1b)E_(i) E_(v)E_(vi) E₄*E₅ E_(f) 1037 E_(1a)E_(ii) E_(v)E_(vi) E₄*E₅ E_(f) 1038 E_(1b)E_(ii) E_(v)E_(vi) E₄*E₅ E_(f) 1039 E_(1a)E_(ii)E_(iib) E_(v)E_(vi) E₄*E₅ E_(f) 1040 E_(1b)E_(ii)E_(iib) E_(v)E_(vi) E₄*E₅ E_(f) 1041 E_(1a)E₄ E_(v)E_(vi) E₄*E₅ E_(f) 1042 E_(1b)E₄ E_(v)E_(vi) E₄*E₅ E_(f) 1043 E_(1a)E_(i)E₄ E_(v)E_(vi) E₄*E₅ E_(f) 1044 E_(1b)E_(i)E₄ E_(v)E_(vi) E₄*E₅ E_(f) 1045 E_(1a)E_(ii)E₄ E_(v)E_(vi) E₄*E₅ E_(f) 1046 E_(1b)E_(ii)E₄ E_(v)E_(vi) E₄*E₅ E_(f) 1047 E_(1a)E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄*E₅ E_(f) 1048 E_(1b)E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄*E₅ E_(f) 1049 E_(1a)E_(iii) E_(v)E_(vi) E₄*E₅ E_(f) 1050 E_(1b)E_(iii) E_(v)E_(vi) E₄*E₅ E_(f) 1051 E_(1a)E_(iii)E₄ E_(v)E_(vi) E₄*E₅ E_(f) 1052 E_(1b)E_(iii)E₄ E_(v)E_(vi) E₄*E₅ E_(f) 1053 E_(1a)E_(iv) E_(v)E_(vi) E₄*E₅ E_(f) 1054 E_(1b)E_(iv) E_(v)E_(vi) E₄*E₅ E_(f) 1055 E_(1a)E_(iv)E₄ E_(v)E_(vi) E₄*E₅ E_(f) 1056 E_(1b)E_(iv)E₄ E_(v)E_(vi) E₄*E₅ E_(f) 1057 E_(1a) AlkLE_(v)E_(vi) E_(f) 1058 E_(1b) AlkLE_(v)E_(vi) E_(f) 1059 E_(1a)E_(i) AlkLE_(v)E_(vi) E_(f) 1060 E_(1b)E_(i) AlkLE_(v)E_(vi) E_(f) 1061 E_(1a)E_(ii) AlkLE_(v)E_(vi) E_(f) 1062 E_(1b)E_(ii) AlkLE_(v)E_(vi) E_(f) 1063 E_(1a)E_(ii)E_(iib) AlkLE_(v)E_(vi) E_(f) 1064 E_(1b)E_(ii)E_(iib) AlkLE_(v)E_(vi) E_(f) 1065 E_(1a)E₄ AlkLE_(v)E_(vi) E_(f) 1066 E_(1b)E₄ AlkLE_(v)E_(vi) E_(f) 1067 E_(1a)E_(i)E₄ AlkLE_(v)E_(vi) E_(f) 1068 E_(1b)E_(i)E₄ AlkLE_(v)E_(vi) E_(f) 1069 E_(1a)E_(ii)E₄ AlkLE_(v)E_(vi) E_(f) 1070 E_(1b)E_(ii)E₄ AlkLE_(v)E_(vi) E_(f) 1071 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E_(f) 1072 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E_(f) 1073 E_(1a)E_(iii) AlkLE_(v)E_(vi) E_(f) 1074 E_(1b)E_(iii) AlkLE_(v)E_(vi) E_(f) 1075 E_(1a)E_(iii)E₄ AlkLE_(v)E_(vi) E_(f) 1076 E_(1b)E_(iii)E₄ AlkLE_(v)E_(vi) E_(f) 1077 E_(1a)E_(iv) AlkLE_(v)E_(vi) E_(f) 1078 E_(1b)E_(iv) AlkLE_(v)E_(vi) E_(f) 1079 E_(1a)E_(iv)E₄ AlkLE_(v)E_(vi) E_(f) 1080 E_(1b)E_(iv)E₄ AlkLE_(v)E_(vi) E_(f) 1081 E_(1a) AlkLE_(v)E_(vi) E₄* E_(f) 1082 E_(1b) AlkLE_(v)E_(vi) E₄* E_(f) 1083 E_(1a)E_(i) AlkLE_(v)E_(vi) E₄* E_(f) 1084 E_(1b)E_(i) AlkLE_(v)E_(vi) E₄* E_(f) 1085 E_(1a)E_(ii) AlkLE_(v)E_(vi) E₄* E_(f) 1086 E_(1b)E_(ii) AlkLE_(v)E_(vi) E₄* E_(f) 1087 E_(1a)E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* E_(f) 1088 E_(1b)E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* E_(f) 1089 E_(1a)E₄ AlkLE_(v)E_(vi) E₄* E_(f) 1090 E_(1b)E₄ AlkLE_(v)E_(vi) E₄* E_(f) 1091 E_(1a)E_(i)E₄ AlkLE_(v)E_(vi) E₄* E_(f) 1092 E_(1b)E_(i)E₄ AlkLE_(v)E_(vi) E₄* E_(f) 1093 E_(1a)E_(ii)E₄ AlkLE_(v)E_(vi) E₄* E_(f) 1094 E_(1b)E_(ii)E₄ AlkLE_(v)E_(vi) E₄* E_(f) 1095 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* E_(f) 1096 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* E_(f) 1097 E_(1a)E_(iii) AlkLE_(v)E_(vi) E₄* E_(f) 1098 E_(1b)E_(iii) AlkLE_(v)E_(vi) E₄* E_(f) 1099 E_(1a)E_(iii)E₄ AlkLE_(v)E_(vi) E₄* E_(f) 1100 E_(1b)E_(iii)E₄ AlkLE_(v)E_(vi) E₄* E_(f) 1101 E_(1a)E_(iv) AlkLE_(v)E_(vi) E₄* E_(f) 1102 E_(1b)E_(iv) AlkLE_(v)E_(vi) E₄* E_(f) 1103 E_(1a)E_(iv)E₄ AlkLE_(v)E_(vi) E₄* E_(f) 1104 E_(1b)E_(iv)E₄ AlkLE_(v)E_(vi) E₄* E_(f) 1105 E_(1a) AlkLE_(v)E_(vi) E₅ E_(f) 1106 E_(1b) AlkLE_(v)E_(vi) E₅ E_(f) 1107 E_(1a)E_(i) AlkLE_(v)E_(vi) E₅ E_(f) 1108 E_(1b)E_(i) AlkLE_(v)E_(vi) E₅ E_(f) 1109 E_(1a)E_(ii) AlkLE_(v)E_(vi) E₅ E_(f) 1110 E_(1b)E_(ii) AlkLE_(v)E_(vi) E₅ E_(f) 1111 E_(1a)E_(ii)E_(iib) AlkLE_(v)E_(vi) E₅ E_(f) 1112 E_(1b)E_(ii)E_(iib) AlkLE_(v)E_(vi) E₅ E_(f) 1113 E_(1a)E₄ AlkLE_(v)E_(vi) E₅ E_(f) 1114 E_(1b)E₄ AlkLE_(v)E_(vi) E₅ E_(f) 1115 E_(1a)E_(i)E₄ AlkLE_(v)E_(vi) E₅ E_(f) 1116 E_(1b)E_(i)E₄ AlkLE_(v)E_(vi) E₅ E_(f) 1117 E_(1a)E_(ii)E₄ AlkLE_(v)E_(vi) E₅ E_(f) 1118 E_(1b)E_(ii)E₄ AlkLE_(v)E_(vi) E₅ E_(f) 1119 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₅ E_(f) 1120 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₅ E_(f) 1121 E_(1a)E_(iii) AlkLE_(v)E_(vi) E₅ E_(f) 1122 E_(1b)E_(iii) AlkLE_(v)E_(vi) E₅ E_(f) 1123 E_(1a)E_(iii)E₄ AlkLE_(v)E_(vi) E₅ E_(f) 1124 E_(1b)E_(iii)E₄ AlkLE_(v)E_(vi) E₅ E_(f) 1125 E_(1a)E_(iv) AlkLE_(v)E_(vi) E₅ E_(f) 1126 E_(1b)E_(iv) AlkLE_(v)E_(vi) E₅ E_(f) 1127 E_(1a)E_(iv)E₄ AlkLE_(v)E_(vi) E₅ E_(f) 1128 E_(1b)E_(iv)E₄ AlkLE_(v)E_(vi) E₅ E_(f) 1129 E_(1a) AlkLE_(v)E_(vi) E₄*E₅ E_(f) 1130 E_(1b) AlkLE_(v)E_(vi) E₄*E₅ E_(f) 1131 E_(1a)E_(i) AlkLE_(v)E_(vi) E₄*E₅ E_(f) 1132 E_(1b)E_(i) AlkLE_(v)E_(vi) E₄*E₅ E_(f) 1133 E_(1a)E_(ii) AlkLE_(v)E_(vi) E₄*E₅ E_(f) 1134 E_(1b)E_(ii) AlkLE_(v)E_(vi) E₄*E₅ E_(f) 1135 E_(1a)E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄*E₅ E_(f) 1136 E_(1b)E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄*E₅ E_(f) 1137 E_(1a)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(f) 1138 E_(1b)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(f) 1139 E_(1a)E_(i)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(f) 1140 E_(1b)E_(i)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(f) 1141 E_(1a)E_(ii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(f) 1142 E_(1b)E_(ii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(f) 1143 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(f) 1144 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(f) 1145 E_(1a)E_(iii) AlkLE_(v)E_(vi) E₄*E₅ E_(f) 1146 E_(1b)E_(iii) AlkLE_(v)E_(vi) E₄*E₅ E_(f) 1147 E_(1a)E_(iii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(f) 1148 E_(1b)E_(iii)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(f) 1149 E_(1a)E_(iv) AlkLE_(v)E_(vi) E₄*E₅ E_(f) 1150 E_(1b)E_(iv) AlkLE_(v)E_(vi) E₄*E₅ E_(f) 1151 E_(1a)E_(iv)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(f) 1152 E_(1b)E_(iv)E₄ AlkLE_(v)E_(vi) E₄*E₅ E_(f) 1153 E_(1a) E_(vii) 1154 E_(1b) E_(vii) 1155 E_(1a)E_(i) E_(vii) 1156 E_(1b)E_(i) E_(vii) 1157 E_(1a)E_(ii) E_(vii) 1158 E_(1b)E_(ii) E_(vii) 1159 E_(1a)E_(ii)E_(iib) E_(vii) 1160 E_(1b)E_(ii)E_(iib) E_(vii) 1161 E_(1a)E₄ E_(vii) 1162 E_(1b)E₄ E_(vii) 1163 E_(1a)E_(i)E₄ E_(vii) 1164 E_(1b)E_(i)E₄ E_(vii) 1165 E_(1a)E_(ii)E₄ E_(vii) 1166 E_(1b)E_(ii)E₄ E_(vii) 1167 E_(1a)E_(ii)E_(iib)E₄ E_(vii) 1168 E_(1b)E_(ii)E_(iib)E₄ E_(vii) 1169 E_(1a)E_(iii) E_(vii) 1170 E_(1b)E_(iii) E_(vii) 1171 E_(1a)E_(iii)E₄ E_(vii) 1172 E_(1b)E_(iii)E₄ E_(vii) 1173 E_(1a)E_(iv) E_(vii) 1174 E_(1b)E_(iv) E_(vii) 1175 E_(1a)E_(iv)E₄ E_(vii) 1176 E_(1b)E_(iv)E₄ E_(vii) 1177 E_(1a) E_(vii) E₄* 1178 E_(1b) E_(vii) E₄* 1179 E_(1a)E_(i) E_(vii) E₄* 1180 E_(1b)E_(i) E_(vii) E₄* 1181 E_(1a)E_(ii) E_(vii) E₄* 1182 E_(1b)E_(ii) E_(vii) E₄* 1183 E_(1a)E_(ii)E_(iib) E_(vii) E₄* 1184 E_(1b)E_(ii)E_(iib) E_(vii) E₄* 1185 E_(1a)E₄ E_(vii) E₄* 1186 E_(1b)E₄ E_(vii) E₄* 1187 E_(1a)E_(i)E₄ E_(vii) E₄* 1188 E_(1b)E_(i)E₄ E_(vii) E₄* 1189 E_(1a)E_(ii)E₄ E_(vii) E₄* 1190 E_(1b)E_(ii)E₄ E_(vii) E₄* 1191 E_(1a)E_(ii)E_(iib)E₄ E_(vii) E₄* 1192 E_(1b)E_(ii)E_(iib)E₄ E_(vii) E₄* 1193 E_(1a)E_(iii) E_(vii) E₄* 1194 E_(1b)E_(iii) E_(vii) E₄* 1195 E_(1a)E_(iii)E₄ E_(vii) E₄* 1196 E_(1b)E_(iii)E₄ E_(vii) E₄* 1197 E_(1a)E_(iv) E_(vii) E₄* 1198 E_(1b)E_(iv) E_(vii) E₄* 1199 E_(1a)E_(iv)E₄ E_(vii) E₄* 1200 E_(1b)E_(iv)E₄ E_(vii) E₄* 1201 E_(1a) E_(vii) E₅ 1202 E_(1b) E_(vii) E₅ 1203 E_(1a)E_(i) E_(vii) E₅ 1204 E_(1b)E_(i) E_(vii) E₅ 1205 E_(1a)E_(ii) E_(vii) E₅ 1206 E_(1b)E_(ii) E_(vii) E₅ 1207 E_(1a)E_(ii)E_(iib) E_(vii) E₅ 1208 E_(1b)E_(ii)E_(iib) E_(vii) E₅ 1209 E_(1a)E₄ E_(vii) E₅ 1210 E_(1b)E₄ E_(vii) E₅ 1211 E_(1a)E_(i)E₄ E_(vii) E₅ 1212 E_(1b)E_(i)E₄ E_(vii) E₅ 1213 E_(1a)E_(ii)E₄ E_(vii) E₅ 1214 E_(1b)E_(ii)E₄ E_(vii) E₅ 1215 E_(1a)E_(ii)E_(iib)E₄ E_(vii) E₅ 1216 E_(1b)E_(ii)E_(iib)E₄ E_(vii) E₅ 1217 E_(1a)E_(iii) E_(vii) E₅ 1218 E_(1b)E_(iii) E_(vii) E₅ 1219 E_(1a)E_(iii)E₄ E_(vii) E₅ 1220 E_(1b)E_(iii)E₄ E_(vii) E₅ 1221 E_(1a)E_(iv) E_(vii) E₅ 1222 E_(1b)E_(iv) E_(vii) E₅ 1223 E_(1a)E_(iv)E₄ E_(vii) E₅ 1224 E_(1b)E_(iv)E₄ E_(vii) E₅ 1225 E_(1a) E_(vii) E₄*E₅ 1226 E_(1b) E_(vii) E₄*E₅ 1227 E_(1a)E_(i) E_(vii) E₄*E₅ 1228 E_(1b)E_(i) E_(vii) E₄*E₅ 1229 E_(1a)E_(ii) E_(vii) E₄*E₅ 1230 E_(1b)E_(ii) E_(vii) E₄*E₅ 1231 E_(1a)E_(ii)E_(iib) E_(vii) E₄*E₅ 1232 E_(1b)E_(ii)E_(iib) E_(vii) E₄*E₅ 1233 E_(1a)E₄ E_(vii) E₄*E₅ 1234 E_(1b)E₄ E_(vii) E₄*E₅ 1235 E_(1a)E_(i)E₄ E_(vii) E₄*E₅ 1236 E_(1b)E_(i)E₄ E_(vii) E₄*E₅ 1237 E_(1a)E_(ii)E₄ E_(vii) E₄*E₅ 1238 E_(1b)E_(ii)E₄ E_(vii) E₄*E₅ 1239 E_(1a)E_(ii)E_(iib)E₄ E_(vii) E₄*E₅ 1240 E_(1b)E_(ii)E_(iib)E₄ E_(vii) E₄*E₅ 1241 E_(1a)E_(iii) E_(vii) E₄*E₅ 1242 E_(1b)E_(iii) E_(vii) E₄*E₅ 1243 E_(1a)E_(iii)E₄ E_(vii) E₄*E₅ 1244 E_(1b)E_(iii)E₄ E_(vii) E₄*E₅ 1245 E_(1a)E_(iv) E_(vii) E₄*E₅ 1246 E_(1b)E_(iv) E_(vii) E₄*E₅ 1247 E_(1a)E_(iv)E₄ E_(vii) E₄*E₅ 1248 E_(1b)E_(iv)E₄ E_(vii) E₄*E₅ 1249 E_(1a) AlkLE_(vii) 1250 E_(1b) AlkLE_(vii) 1251 E_(1a)E_(i) AlkLE_(vii) 1252 E_(1b)E_(i) AlkLE_(vii) 1253 E_(1a)E_(ii) AlkLE_(vii) 1254 E_(1b)E_(ii) AlkLE_(vii) 1255 E_(1a)E_(ii)E_(iib) AlkLE_(vii) 1256 E_(1b)E_(ii)E_(iib) AlkLE_(vii) 1257 E_(1a)E₄ AlkLE_(vii) 1258 E_(1b)E₄ AlkLE_(vii) 1259 E_(1a)E_(i)E₄ AlkLE_(vii) 1260 E_(1b)E_(i)E₄ AlkLE_(vii) 1261 E_(1a)E_(ii)E₄ AlkLE_(vii) 1262 E_(1b)E_(ii)E₄ AlkLE_(vii) 1263 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(vii) 1264 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(vii) 1265 E_(1a)E_(iii) AlkLE_(vii) 1266 E_(1b)E_(iii) AlkLE_(vii) 1267 E_(1a)E_(iii)E₄ AlkLE_(vii) 1268 E_(1b)E_(iii)E₄ AlkLE_(vii) 1269 E_(1a)E_(iv) AlkLE_(vii) 1270 E_(1b)E_(iv) AlkLE_(vii) 1271 E_(1a)E_(iv)E₄ AlkLE_(vii) 1272 E_(1b)E_(iv)E₄ AlkLE_(vii) 1273 E_(1a) AlkLE_(vii) E₄* 1274 E_(1b) AlkLE_(vii) E₄* 1275 E_(1a)E_(i) AlkLE_(vii) E₄* 1276 E_(1b)E_(i) AlkLE_(vii) E₄* 1277 E_(1a)E_(ii) AlkLE_(vii) E₄* 1278 E_(1b)E_(ii) AlkLE_(vii) E₄* 1279 E_(1a)E_(ii)E_(iib) AlkLE_(vii) E₄* 1280 E_(1b)E_(ii)E_(iib) AlkLE_(vii) E₄* 1281 E_(1a)E₄ AlkLE_(vii) E₄* 1282 E_(1b)E₄ AlkLE_(vii) E₄* 1283 E_(1a)E_(i)E₄ AlkLE_(vii) E₄* 1284 E_(1b)E_(i)E₄ AlkLE_(vii) E₄* 1285 E_(1a)E_(ii)E₄ AlkLE_(vii) E₄* 1286 E_(1b)E_(ii)E₄ AlkLE_(vii) E₄* 1287 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* 1288 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* 1289 E_(1a)E_(iii) AlkLE_(vii) E₄* 1290 E_(1b)E_(iii) AlkLE_(vii) E₄* 1291 E_(1a)E_(iii)E₄ AlkLE_(vii) E₄* 1292 E_(1b)E_(iii)E₄ AlkLE_(vii) E₄* 1293 E_(1a)E_(iv) AlkLE_(vii) E₄* 1294 E_(1b)E_(iv) AlkLE_(vii) E₄* 1295 E_(1a)E_(iv)E₄ AlkLE_(vii) E₄* 1296 E_(1b)E_(iv)E₄ AlkLE_(vii) E₄* 1297 E_(1a) AlkLE_(vii) E₅ 1298 E_(1b) AlkLE_(vii) E₅ 1299 E_(1a)E_(i) AlkLE_(vii) E₅ 1300 E_(1b)E_(i) AlkLE_(vii) E₅ 1301 E_(1a)E_(ii) AlkLE_(vii) E₅ 1302 E_(1b)E_(ii) AlkLE_(vii) E₅ 1303 E_(1a)E_(ii)E_(iib) AlkLE_(vii) E₅ 1304 E_(1b)E_(ii)E_(iib) AlkLE_(vii) E₅ 1305 E_(1a)E₄ AlkLE_(vii) E₅ 1306 E_(1b)E₄ AlkLE_(vii) E₅ 1307 E_(1a)E_(i)E₄ AlkLE_(vii) E₅ 1308 E_(1b)E_(i)E₄ AlkLE_(vii) E₅ 1309 E_(1a)E_(ii)E₄ AlkLE_(vii) E₅ 1310 E_(1b)E_(ii)E₄ AlkLE_(vii) E₅ 1311 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(vii) E₅ 1312 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(vii) E₅ 1313 E_(1a)E_(iii) AlkLE_(vii) E₅ 1314 E_(1b)E_(iii) AlkLE_(vii) E₅ 1315 E_(1a)E_(iii)E₄ AlkLE_(vii) E₅ 1316 E_(1b)E_(iii)E₄ AlkLE_(vii) E₅ 1317 E_(1a)E_(iv) AlkLE_(vii) E₅ 1318 E_(1b)E_(iv) AlkLE_(vii) E₅ 1319 E_(1a)E_(iv)E₄ AlkLE_(vii) E₅ 1320 E_(1b)E_(iv)E₄ AlkLE_(vii) E₅ 1321 E_(1a) AlkLE_(vii) E₄*E₅ 1322 E_(1b) AlkLE_(vii) E₄*E₅ 1323 E_(1a)E_(i) AlkLE_(vii) E₄*E₅ 1324 E_(1b)E_(i) AlkLE_(vii) E₄*E₅ 1325 E_(1a)E_(ii) AlkLE_(vii) E₄*E₅ 1326 E_(1b)E_(ii) AlkLE_(vii) E₄*E₅ 1327 E_(1a)E_(ii)E_(iib) AlkLE_(vii) E₄*E₅ 1328 E_(1b)E_(ii)E_(iib) AlkLE_(vii) E₄*E₅ 1329 E_(1a)E₄ AlkLE_(vii) E₄*E₅ 1330 E_(1b)E₄ AlkLE_(vii) E₄*E₅ 1331 E_(1a)E_(i)E₄ AlkLE_(vii) E₄*E₅ 1332 E_(1b)E_(i)E₄ AlkLE_(vii) E₄*E₅ 1333 E_(1a)E_(ii)E₄ AlkLE_(vii) E₄*E₅ 1334 E_(1b)E_(ii)E₄ AlkLE_(vii) E₄*E₅ 1335 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(vii) E₄*E₅ 1336 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(vii) E₄*E₅ 1337 E_(1a)E_(iii) AlkLE_(vii) E₄*E₅ 1338 E_(1b)E_(iii) AlkLE_(vii) E₄*E₅ 1339 E_(1a)E_(iii)E₄ AlkLE_(vii) E₄*E₅ 1340 E_(1b)E_(iii)E₄ AlkLE_(vii) E₄*E₅ 1341 E_(1a)E_(iv) AlkLE_(vii) E₄*E₅ 1342 E_(1b)E_(iv) AlkLE_(vii) E₄*E₅ 1343 E_(1a)E_(iv)E₄ AlkLE_(vii) E₄*E₅ 1344 E_(1b)E_(iv)E₄ AlkLE_(vii) E₄*E₅ 1345 E_(1a) E_(vii) E_(a) 1346 E_(1b) E_(vii) E_(a) 1347 E_(1a)E_(i) E_(vii) E_(a) 1348 E_(1b)E_(i) E_(vii) E_(a) 1349 E_(1a)E_(ii) E_(vii) E_(a) 1350 E_(1b)E_(ii) E_(vii) E_(a) 1351 E_(1a)E_(ii)E_(iib) E_(vii) E_(a) 1352 E_(1b)E_(ii)E_(iib) E_(vii) E_(a) 1353 E_(1a)E₄ E_(vii) E_(a) 1354 E_(1b)E₄ E_(vii) E_(a) 1355 E_(1a)E_(i)E₄ E_(vii) E_(a) 1356 E_(1b)E_(i)E₄ E_(vii) E_(a) 1357 E_(1a)E_(ii)E₄ E_(vii) E_(a) 1358 E_(1b)E_(ii)E₄ E_(vii) E_(a) 1359 E_(1a)E_(ii)E_(iib)E₄ E_(vii) E_(a) 1360 E_(1b)E_(ii)E_(iib)E₄ E_(vii) E_(a) 1361 E_(1a)E_(iii) E_(vii) E_(a) 1362 E_(1b)E_(iii) E_(vii) E_(a) 1363 E_(1a)E_(iii)E₄ E_(vii) E_(a) 1364 E_(1b)E_(iii)E₄ E_(vii) E_(a) 1365 E_(1a)E_(iv) E_(vii) E_(a) 1366 E_(1b)E_(iv) E_(vii) E_(a) 1367 E_(1a)E_(iv)E₄ E_(vii) E_(a) 1368 E_(1b)E_(iv)E₄ E_(vii) E_(a) 1369 E_(1a) E_(vii) E₄* E_(a) 1370 E_(1b) E_(vii) E₄* E_(a) 1371 E_(1a)E_(i) E_(vii) E₄* E_(a) 1372 E_(1b)E_(i) E_(vii) E₄* E_(a) 1373 E_(1a)E_(ii) E_(vii) E₄* E_(a) 1374 E_(1b)E_(ii) E_(vii) E₄* E_(a) 1375 E_(1a)E_(ii)E_(iib) E_(vii) E₄* E_(a) 1376 E_(1b)E_(ii)E_(iib) E_(vii) E₄* E_(a) 1377 E_(1a)E₄ E_(vii) E₄* E_(a) 1378 E_(1b)E₄ E_(vii) E₄* E_(a) 1379 E_(1a)E_(i)E₄ E_(vii) E₄* E_(a) 1380 E_(1b)E_(i)E₄ E_(vii) E₄* E_(a) 1381 E_(1a)E_(ii)E₄ E_(vii) E₄* E_(a) 1382 E_(1b)E_(ii)E₄ E_(vii) E₄* E_(a) 1383 E_(1a)E_(ii)E_(iib)E₄ E_(vii) E₄* E_(a) 1384 E_(1b)E_(ii)E_(iib)E₄ E_(vii) E₄* E_(a) 1385 E_(1a)E_(iii) E_(vii) E₄* E_(a) 1386 E_(1b)E_(iii) E_(vii) E₄* E_(a) 1387 E_(1a)E_(iii)E₄ E_(vii) E₄* E_(a) 1388 E_(1b)E_(iii)E₄ E_(vii) E₄* E_(a) 1389 E_(1a)E_(iv) E_(vii) E₄* E_(a) 1390 E_(1b)E_(iv) E_(vii) E₄* E_(a) 1391 E_(1a)E_(iv)E₄ E_(vii) E₄* E_(a) 1392 E_(1b)E_(iv)E₄ E_(vii) E₄* E_(a) 1393 E_(1a) E_(vii) E₅ E_(a) 1394 E_(1b) E_(vii) E₅ E_(a) 1395 E_(1a)E_(i) E_(vii) E₅ E_(a) 1396 E_(1b)E_(i) E_(vii) E₅ E_(a) 1397 E_(1a)E_(ii) E_(vii) E₅ E_(a) 1398 E_(1b)E_(ii) E_(vii) E₅ E_(a) 1399 E_(1a)E_(ii)E_(iib) E_(vii) E₅ E_(a) 1400 E_(1b)E_(ii)E_(iib) E_(vii) E₅ E_(a) 1401 E_(1a)E₄ E_(vii) E₅ E_(a) 1402 E_(1b)E₄ E_(vii) E₅ E_(a) 1403 E_(1a)E_(i)E₄ E_(vii) E₅ E_(a) 1404 E_(1b)E_(i)E₄ E_(vii) E₅ E_(a) 1405 E_(1a)E_(ii)E₄ E_(vii) E₅ E_(a) 1406 E_(1b)E_(ii)E₄ E_(vii) E₅ E_(a) 1407 E_(1a)E_(ii)E_(iib)E₄ E_(vii) E₅ E_(a) 1408 E_(1b)E_(ii)E_(iib)E₄ E_(vii) E₅ E_(a) 1409 E_(1a)E_(iii) E_(vii) E₅ E_(a) 1410 E_(1b)E_(iii) E_(vii) E₅ E_(a) 1411 E_(1a)E_(iii)E₄ E_(vii) E₅ E_(a) 1412 E_(1b)E_(iii)E₄ E_(vii) E₅ E_(a) 1413 E_(1a)E_(iv) E_(vii) E₅ E_(a) 1414 E_(1b)E_(iv) E_(vii) E₅ E_(a) 1415 E_(1a)E_(iv)E₄ E_(vii) E₅ E_(a) 1416 E_(1b)E_(iv)E₄ E_(vii) E₅ E_(a) 1417 E_(1a) E_(vii) E₄*E₅ E_(a) 1418 E_(1b) E_(vii) E₄*E₅ E_(a) 1419 E_(1a)E_(i) E_(vii) E₄*E₅ E_(a) 1420 E_(1b)E_(i) E_(vii) E₄*E₅ E_(a) 1421 E_(1a)E_(ii) E_(vii) E₄*E₅ E_(a) 1422 E_(1b)E_(ii) E_(vii) E₄*E₅ E_(a) 1423 E_(1a)E_(ii)E_(iib) E_(vii) E₄*E₅ E_(a) 1424 E_(1b)E_(ii)E_(iib) E_(vii) E₄*E₅ E_(a) 1425 E_(1a)E₄ E_(vii) E₄*E₅ E_(a) 1426 E_(1b)E₄ E_(vii) E₄*E₅ E_(a) 1427 E_(1a)E_(i)E₄ E_(vii) E₄*E₅ E_(a) 1428 E_(1b)E_(i)E₄ E_(vii) E₄*E₅ E_(a) 1429 E_(1a)E_(ii)E₄ E_(vii) E₄*E₅ E_(a) 1430 E_(1b)E_(ii)E₄ E_(vii) E₄*E₅ E_(a) 1431 E_(1a)E_(ii)E_(iib)E₄ E_(vii) E₄*E₅ E_(a) 1432 E_(1b)E_(ii)E_(iib)E₄ E_(vii) E₄*E₅ E_(a) 1433 E_(1a)E_(iii) E_(vii) E₄*E₅ E_(a) 1434 E_(1b)E_(iii) E_(vii) E₄*E₅ E_(a) 1435 E_(1a)E_(iii)E₄ E_(vii) E₄*E₅ E_(a) 1436 E_(1b)E_(iii)E₄ E_(vii) E₄*E₅ E_(a) 1437 E_(1a)E_(iv) E_(vii) E₄*E₅ E_(a) 1438 E_(1b)E_(iv) E_(vii) E₄*E₅ E_(a) 1439 E_(1a)E_(iv)E₄ E_(vii) E₄*E₅ E_(a) 1440 E_(1b)E_(iv)E₄ E_(vii) E₄*E₅ E_(a) 1441 E_(1a) AlkLE_(vii) E_(a) 1442 E_(1b) AlkLE_(vii) E_(a) 1443 E_(1a)E_(i) AlkLE_(vii) E_(a) 1444 E_(1b)E_(i) AlkLE_(vii) E_(a) 1445 E_(1a)E_(ii) AlkLE_(vii) E_(a) 1446 E_(1b)E_(ii) AlkLE_(vii) E_(a) 1447 E_(1a)E_(ii)E_(iib) AlkLE_(vii) E_(a) 1448 E_(1b)E_(ii)E_(iib) AlkLE_(vii) E_(a) 1449 E_(1a)E₄ AlkLE_(vii) E_(a) 1450 E_(1b)E₄ AlkLE_(vii) E_(a) 1451 E_(1a)E_(i)E₄ AlkLE_(vii) E_(a) 1452 E_(1b)E_(i)E₄ AlkLE_(vii) E_(a) 1453 E_(1a)E_(ii)E₄ AlkLE_(vii) E_(a) 1454 E_(1b)E_(ii)E₄ AlkLE_(vii) E_(a) 1455 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(vii) E_(a) 1456 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(vii) E_(a) 1457 E_(1a)E_(iii) AlkLE_(vii) E_(a) 1458 E_(1b)E_(iii) AlkLE_(vii) E_(a) 1459 E_(1a)E_(iii)E₄ AlkLE_(vii) E_(a) 1460 E_(1b)E_(iii)E₄ AlkLE_(vii) E_(a) 1461 E_(1a)E_(iv) AlkLE_(vii) E_(a) 1462 E_(1b)E_(iv) AlkLE_(vii) E_(a) 1463 E_(1a)E_(iv)E₄ AlkLE_(vii) E_(a) 1464 E_(1b)E_(iv)E₄ AlkLE_(vii) E_(a) 1465 E_(1a) AlkLE_(vii) E₄* E_(a) 1466 E_(1b) AlkLE_(vii) E₄* E_(a) 1467 E_(1a)E_(i) AlkLE_(vii) E₄* E_(a) 1468 E_(1b)E_(i) AlkLE_(vii) E₄* E_(a) 1469 E_(1a)E_(ii) AlkLE_(vii) E₄* E_(a) 1470 E_(1b)E_(ii) AlkLE_(vii) E₄* E_(a) 1471 E_(1a)E_(ii)E_(iib) AlkLE_(vii) E₄* E_(a) 1472 E_(1b)E_(ii)E_(iib) AlkLE_(vii) E₄* E_(a) 1473 E_(1a)E₄ AlkLE_(vii) E₄* E_(a) 1474 E_(1b)E₄ AlkLE_(vii) E₄* E_(a) 1475 E_(1a)E_(i)E₄ AlkLE_(vii) E₄* E_(a) 1476 E_(1b)E_(i)E₄ AlkLE_(vii) E₄* E_(a) 1477 E_(1a)E_(ii)E₄ AlkLE_(vii) E₄* E_(a) 1478 E_(1b)E_(ii)E₄ AlkLE_(vii) E₄* E_(a) 1479 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* E_(a) 1480 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* E_(a) 1481 E_(1a)E_(iii) AlkLE_(vii) E₄* E_(a) 1482 E_(1b)E_(iii) AlkLE_(vii) E₄* E_(a) 1483 E_(1a)E_(iii)E₄ AlkLE_(vii) E₄* E_(a) 1484 E_(1b)E_(iii)E₄ AlkLE_(vii) E₄* E_(a) 1485 E_(1a)E_(iv) AlkLE_(vii) E₄* E_(a) 1486 E_(1b)E_(iv) AlkLE_(vii) E₄* E_(a) 1487 E_(1a)E_(iv)E₄ AlkLE_(vii) E₄* E_(a) 1488 E_(1b)E_(iv)E₄ AlkLE_(vii) E₄* E_(a) 1489 E_(1a) AlkLE_(vii) E₅ E_(a) 1490 E_(1b) AlkLE_(vii) E₅ E_(a) 1491 E_(1a)E_(i) AlkLE_(vii) E₅ E_(a) 1492 E_(1b)E_(i) AlkLE_(vii) E₅ E_(a) 1493 E_(1a)E_(ii) AlkLE_(vii) E₅ E_(a) 1494 E_(1b)E_(ii) AlkLE_(vii) E₅ E_(a) 1495 E_(1a)E_(ii)E_(iib) AlkLE_(vii) E₅ E_(a) 1496 E_(1b)E_(ii)E_(iib) AlkLE_(vii) E₅ E_(a) 1497 E_(1a)E₄ AlkLE_(vii) E₅ E_(a) 1498 E_(1b)E₄ AlkLE_(vii) E₅ E_(a) 1499 E_(1a)E_(i)E₄ AlkLE_(vii) E₅ E_(a) 1500 E_(1b)E_(i)E₄ AlkLE_(vii) E₅ E_(a) 1501 E_(1a)E_(ii)E₄ AlkLE_(vii) E₅ E_(a) 1502 E_(1b)E_(ii)E₄ AlkLE_(vii) E₅ E_(a) 1503 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(vii) E₅ E_(a) 1504 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(vii) E₅ E_(a) 1505 E_(1a)E_(iii) AlkLE_(vii) E₅ E_(a) 1506 E_(1b)E_(iii) AlkLE_(vii) E₅ E_(a) 1507 E_(1a)E_(iii)E₄ AlkLE_(vii) E₅ E_(a) 1508 E_(1b)E_(iii)E₄ AlkLE_(vii) E₅ E_(a) 1509 E_(1a)E_(iv) AlkLE_(vii) E₅ E_(a) 1510 E_(1b)E_(iv) AlkLE_(vii) E₅ E_(a) 1511 E_(1a)E_(iv)E₄ AlkLE_(vii) E₅ E_(a) 1512 E_(1b)E_(iv)E₄ AlkLE_(vii) E₅ E_(a) 1513 E_(1a) AlkLE_(vii) E₄*E₅ E_(a) 1514 E_(1b) AlkLE_(vii) E₄*E₅ E_(a) 1515 E_(1a)E_(i) AlkLE_(vii) E₄*E₅ E_(a) 1516 E_(1b)E_(i) AlkLE_(vii) E₄*E₅ E_(a) 1517 E_(1a)E_(ii) AlkLE_(vii) E₄*E₅ E_(a) 1518 E_(1b)E_(ii) AlkLE_(vii) E₄*E₅ E_(a) 1519 E_(1a)E_(ii)E_(iib) AlkLE_(vii) E₄*E₅ E_(a) 1520 E_(1b)E_(ii)E_(iib) AlkLE_(vii) E₄*E₅ E_(a) 1521 E_(1a)E₄ AlkLE_(vii) E₄*E₅ E_(a) 1522 E_(1b)E₄ AlkLE_(vii) E₄*E₅ E_(a) 1523 E_(1a)E_(i)E₄ AlkLE_(vii) E₄*E₅ E_(a) 1524 E_(1b)E_(i)E₄ AlkLE_(vii) E₄*E₅ E_(a) 1525 E_(1a)E_(ii)E₄ AlkLE_(vii) E₄*E₅ E_(a) 1526 E_(1b)E_(ii)E₄ AlkLE_(vii) E₄*E₅ E_(a) 1527 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(vii) E₄*E₅ E_(a) 1528 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(vii) E₄*E₅ E_(a) 1529 E_(1a)E_(iii) AlkLE_(vii) E₄*E₅ E_(a) 1530 E_(1b)E_(iii) AlkLE_(vii) E₄*E₅ E_(a) 1531 E_(1a)E_(iii)E₄ AlkLE_(vii) E₄*E₅ E_(a) 1532 E_(1b)E_(iii)E₄ AlkLE_(vii) E₄*E₅ E_(a) 1533 E_(1a)E_(iv) AlkLE_(vii) E₄*E₅ E_(a) 1534 E_(1b)E_(iv) AlkLE_(vii) E₄*E₅ E_(a) 1535 E_(1a)E_(iv)E₄ AlkLE_(vii) E₄*E₅ E_(a) 1536 E_(1b)E_(iv)E₄ AlkLE_(vii) E₄*E₅ E_(a) 1537 E_(1a) E_(vii) E_(b) 1538 E_(1b) E_(vii) E_(b) 1539 E_(1a)E_(i) E_(vii) E_(b) 1540 E_(1b)E_(i) E_(vii) E_(b) 1541 E_(1a)E_(ii) E_(vii) E_(b) 1542 E_(1b)E_(ii) E_(vii) E_(b) 1543 E_(1a)E_(ii)E_(iib) E_(vii) E_(b) 1544 E_(1b)E_(ii)E_(iib) E_(vii) E_(b) 1545 E_(1a)E₄ E_(vii) E_(b) 1546 E_(1b)E₄ E_(vii) E_(b) 1547 E_(1a)E_(i)E₄ E_(vii) E_(b) 1548 E_(1b)E_(i)E₄ E_(vii) E_(b) 1549 E_(1a)E_(ii)E₄ E_(vii) E_(b) 1550 E_(1b)E_(ii)E₄ E_(vii) E_(b) 1551 E_(1a)E_(ii)E_(iib)E₄ E_(vii) E_(b) 1552 E_(1b)E_(ii)E_(iib)E₄ E_(vii) E_(b) 1553 E_(1a)E_(iii) E_(vii) E_(b) 1554 E_(1b)E_(iii) E_(vii) E_(b) 1555 E_(1a)E_(iii)E₄ E_(vii) E_(b) 1556 E_(1b)E_(iii)E₄ E_(vii) E_(b) 1557 E_(1a)E_(iv) E_(vii) E_(b) 1558 E_(1b)E_(iv) E_(vii) E_(b) 1559 E_(1a)E_(iv)E₄ E_(vii) E_(b) 1560 E_(1b)E_(iv)E₄ E_(vii) E_(b) 1561 E_(1a) E_(vii) E₄* E_(b) 1562 E_(1b) E_(vii) E₄* E_(b) 1563 E_(1a)E_(i) E_(vii) E₄* E_(b) 1564 E_(1b)E_(i) E_(vii) E₄* E_(b) 1565 E_(1a)E_(ii) E_(vii) E₄* E_(b) 1566 E_(1b)E_(ii) E_(vii) E₄* E_(b) 1567 E_(1a)E_(ii)E_(iib) E_(vii) E₄* E_(b) 1568 E_(1b)E_(ii)E_(iib) E_(vii) E₄* E_(b) 1569 E_(1a)E₄ E_(vii) E₄* E_(b) 1570 E_(1b)E₄ E_(vii) E₄* E_(b) 1571 E_(1a)E_(i)E₄ E_(vii) E₄* E_(b) 1572 E_(1b)E_(i)E₄ E_(vii) E₄* E_(b) 1573 E_(1a)E_(ii)E₄ E_(vii) E₄* E_(b) 1574 E_(1b)E_(ii)E₄ E_(vii) E₄* E_(b) 1575 E_(1a)E_(ii)E_(iib)E₄ E_(vii) E₄* E_(b) 1576 E_(1b)E_(ii)E_(iib)E₄ E_(vii) E₄* E_(b) 1577 E_(1a)E_(iii) E_(vii) E₄* E_(b) 1578 E_(1b)E_(iii) E_(vii) E₄* E_(b) 1579 E_(1a)E_(iii)E₄ E_(vii) E₄* E_(b) 1580 E_(1b)E_(iii)E₄ E_(vii) E₄* E_(b) 1581 E_(1a)E_(iv) E_(vii) E₄* E_(b) 1582 E_(1b)E_(iv) E_(vii) E₄* E_(b) 1583 E_(1a)E_(iv)E₄ E_(vii) E₄* E_(b) 1584 E_(1b)E_(iv)E₄ E_(vii) E₄* E_(b) 1585 E_(1a) E_(vii) E₅ E_(b) 1586 E_(1b) E_(vii) E₅ E_(b) 1587 E_(1a)E_(i) E_(vii) E₅ E_(b) 1588 E_(1b)E_(i) E_(vii) E₅ E_(b) 1589 E_(1a)E_(ii) E_(vii) E₅ E_(b) 1590 E_(1b)E_(ii) E_(vii) E₅ E_(b) 1591 E_(1a)E_(ii)E_(iib) E_(vii) E₅ E_(b) 1592 E_(1b)E_(ii)E_(iib) E_(vii) E₅ E_(b) 1593 E_(1a)E₄ E_(vii) E₅ E_(b) 1594 E_(1b)E₄ E_(vii) E₅ E_(b) 1595 E_(1a)E_(i)E₄ E_(vii) E₅ E_(b) 1596 E_(1b)E_(i)E₄ E_(vii) E₅ E_(b) 1597 E_(1a)E_(ii)E₄ E_(vii) E₅ E_(b) 1598 E_(1b)E_(ii)E₄ E_(vii) E₅ E_(b) 1599 E_(1a)E_(ii)E_(iib)E₄ E_(vii) E₅ E_(b) 1600 E_(1b)E_(ii)E_(iib)E₄ E_(vii) E₅ E_(b) 1601 E_(1a)E_(iii) E_(vii) E₅ E_(b) 1602 E_(1b)E_(iii) E_(vii) E₅ E_(b) 1603 E_(1a)E_(iii)E₄ E_(vii) E₅ E_(b) 1604 E_(1b)E_(iii)E₄ E_(vii) E₅ E_(b) 1605 E_(1a)E_(iv) E_(vii) E₅ E_(b) 1606 E_(1b)E_(iv) E_(vii) E₅ E_(b) 1607 E_(1a)E_(iv)E₄ E_(vii) E₅ E_(b) 1608 E_(1b)E_(iv)E₄ E_(vii) E₅ E_(b) 1609 E_(1a) E_(vii) E₄*E₅ E_(b) 1610 E_(1b) E_(vii) E₄*E₅ E_(b) 1611 E_(1a)E_(i) E_(vii) E₄*E₅ E_(b) 1612 E_(1b)E_(i) E_(vii) E₄*E₅ E_(b) 1613 E_(1a)E_(ii) E_(vii) E₄*E₅ E_(b) 1614 E_(1b)E_(ii) E_(vii) E₄*E₅ E_(b) 1615 E_(1a)E_(ii)E_(iib) E_(vii) E₄*E₅ E_(b) 1616 E_(1b)E_(ii)E_(iib) E_(vii) E₄*E₅ E_(b) 1617 E_(1a)E₄ E_(vii) E₄*E₅ E_(b) 1618 E_(1b)E₄ E_(vii) E₄*E₅ E_(b) 1619 E_(1a)E_(i)E₄ E_(vii) E₄*E₅ E_(b) 1620 E_(1b)E_(i)E₄ E_(vii) E₄*E₅ E_(b) 1621 E_(1a)E_(ii)E₄ E_(vii) E₄*E₅ E_(b) 1622 E_(1b)E_(ii)E₄ E_(vii) E₄*E₅ E_(b) 1623 E_(1a)E_(ii)E_(iib)E₄ E_(vii) E₄*E₅ E_(b) 1624 E_(1b)E_(ii)E_(iib)E₄ E_(vii) E₄*E₅ E_(b) 1625 E_(1a)E_(iii) E_(vii) E₄*E₅ E_(b) 1626 E_(1b)E_(iii) E_(vii) E₄*E₅ E_(b) 1627 E_(1a)E_(iii)E₄ E_(vii) E₄*E₅ E_(b) 1628 E_(1b)E_(iii)E₄ E_(vii) E₄*E₅ E_(b) 1629 E_(1a)E_(iv) E_(vii) E₄*E₅ E_(b) 1630 E_(1b)E_(iv) E_(vii) E₄*E₅ E_(b) 1631 E_(1a)E_(iv)E₄ E_(vii) E₄*E₅ E_(b) 1632 E_(1b)E_(iv)E₄ E_(vii) E₄*E₅ E_(b) 1633 E_(1a) AlkLE_(vii) E_(b) 1634 E_(1b) AlkLE_(vii) E_(b) 1635 E_(1a)E_(i) AlkLE_(vii) E_(b) 1636 E_(1b)E_(i) AlkLE_(vii) E_(b) 1637 E_(1a)E_(ii) AlkLE_(vii) E_(b) 1638 E_(1b)E_(ii) AlkLE_(vii) E_(b) 1639 E_(1a)E_(ii)E_(iib) AlkLE_(vii) E_(b) 1640 E_(1b)E_(ii)E_(iib) AlkLE_(vii) E_(b) 1641 E_(1a)E₄ AlkLE_(vii) E_(b) 1642 E_(1b)E₄ AlkLE_(vii) E_(b) 1643 E_(1a)E_(i)E₄ AlkLE_(vii) E_(b) 1644 E_(1b)E_(i)E₄ AlkLE_(vii) E_(b) 1645 E_(1a)E_(ii)E₄ AlkLE_(vii) E_(b) 1646 E_(1b)E_(ii)E₄ AlkLE_(vii) E_(b) 1647 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(vii) E_(b) 1648 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(vii) E_(b) 1649 E_(1a)E_(iii) AlkLE_(vii) E_(b) 1650 E_(1b)E_(iii) AlkLE_(vii) E_(b) 1651 E_(1a)E_(iii)E₄ AlkLE_(vii) E_(b) 1652 E_(1b)E_(iii)E₄ AlkLE_(vii) E_(b) 1653 E_(1a)E_(iv) AlkLE_(vii) E_(b) 1654 E_(1b)E_(iv) AlkLE_(vii) E_(b) 1655 E_(1a)E_(iv)E₄ AlkLE_(vii) E_(b) 1656 E_(1b)E_(iv)E₄ AlkLE_(vii) E_(b) 1657 E_(1a) AlkLE_(vii) E₄* E_(b) 1658 E_(1b) AlkLE_(vii) E₄* E_(b) 1659 E_(1a)E_(i) AlkLE_(vii) E₄* E_(b) 1660 E_(1b)E_(i) AlkLE_(vii) E₄* E_(b) 1661 E_(1a)E_(ii) AlkLE_(vii) E₄* E_(b) 1662 E_(1b)E_(ii) AlkLE_(vii) E₄* E_(b) 1663 E_(1a)E_(ii)E_(iib) AlkLE_(vii) E₄* E_(b) 1664 E_(1b)E_(ii)E_(iib) AlkLE_(vii) E₄* E_(b) 1665 E_(1a)E₄ AlkLE_(vii) E₄* E_(b) 1666 E_(1b)E₄ AlkLE_(vii) E₄* E_(b) 1667 E_(1a)E_(i)E₄ AlkLE_(vii) E₄* E_(b) 1668 E_(1b)E_(i)E₄ AlkLE_(vii) E₄* E_(b) 1669 E_(1a)E_(ii)E₄ AlkLE_(vii) E₄* E_(b) 1670 E_(1b)E_(ii)E₄ AlkLE_(vii) E₄* E_(b) 1671 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* E_(b) 1672 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* E_(b) 1673 E_(1a)E_(iii) AlkLE_(vii) E₄* E_(b) 1674 E_(1b)E_(iii) AlkLE_(vii) E₄* E_(b) 1675 E_(1a)E_(iii)E₄ AlkLE_(vii) E₄* E_(b) 1676 E_(1b)E_(iii)E₄ AlkLE_(vii) E₄* E_(b) 1677 E_(1a)E_(iv) AlkLE_(vii) E₄* E_(b) 1678 E_(1b)E_(iv) AlkLE_(vii) E₄* E_(b) 1679 E_(1a)E_(iv)E₄ AlkLE_(vii) E₄* E_(b) 1680 E_(1b)E_(iv)E₄ AlkLE_(vii) E₄* E_(b) 1681 E_(1a) AlkLE_(vii) E₅ E_(b) 1682 E_(1b) AlkLE_(vii) E₅ E_(b) 1683 E_(1a)E_(i) AlkLE_(vii) E₅ E_(b) 1684 E_(1b)E_(i) AlkLE_(vii) E₅ E_(b) 1685 E_(1a)E_(ii) AlkLE_(vii) E₅ E_(b) 1686 E_(1b)E_(ii) AlkLE_(vii) E₅ E_(b) 1687 E_(1a)E_(ii)E_(iib) AlkLE_(vii) E₅ E_(b) 1688 E_(1b)E_(ii)E_(iib) AlkLE_(vii) E₅ E_(b) 1689 E_(1a)E₄ AlkLE_(vii) E₅ E_(b) 1690 E_(1b)E₄ AlkLE_(vii) E₅ E_(b) 1691 E_(1a)E_(i)E₄ AlkLE_(vii) E₅ E_(b) 1692 E_(1b)E_(i)E₄ AlkLE_(vii) E₅ E_(b) 1693 E_(1a)E_(ii)E₄ AlkLE_(vii) E₅ E_(b) 1694 E_(1b)E_(ii)E₄ AlkLE_(vii) E₅ E_(b) 1695 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(vii) E₅ E_(b) 1696 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(vii) E₅ E_(b) 1697 E_(1a)E_(iii) AlkLE_(vii) E₅ E_(b) 1698 E_(1b)E_(iii) AlkLE_(vii) E₅ E_(b) 1699 E_(1a)E_(iii)E₄ AlkLE_(vii) E₅ E_(b) 1700 E_(1b)E_(iii)E₄ AlkLE_(vii) E₅ E_(b) 1701 E_(1a)E_(iv) AlkLE_(vii) E₅ E_(b) 1702 E_(1b)E_(iv) AlkLE_(vii) E₅ E_(b) 1703 E_(1a)E_(iv)E₄ AlkLE_(vii) E₅ E_(b) 1704 E_(1b)E_(iv)E₄ AlkLE_(vii) E₅ E_(b) 1705 E_(1a) AlkLE_(vii) E₄*E₅ E_(b) 1706 E_(1b) AlkLE_(vii) E₄*E₅ E_(b) 1707 E_(1a)E_(i) AlkLE_(vii) E₄*E₅ E_(b) 1708 E_(1b)E_(i) AlkLE_(vii) E₄*E₅ E_(b) 1709 E_(1a)E_(ii) AlkLE_(vii) E₄*E₅ E_(b) 1710 E_(1b)E_(ii) AlkLE_(vii) E₄*E₅ E_(b) 1711 E_(1a)E_(ii)E_(iib) AlkLE_(vii) E₄*E₅ E_(b) 1712 E_(1b)E_(ii)E_(iib) AlkLE_(vii) E₄*E₅ E_(b) 1713 E_(1a)E₄ AlkLE_(vii) E₄*E₅ E_(b) 1714 E_(1b)E₄ AlkLE_(vii) E₄*E₅ E_(b) 1715 E_(1a)E_(i)E₄ AlkLE_(vii) E₄*E₅ E_(b) 1716 E_(1b)E_(i)E₄ AlkLE_(vii) E₄*E₅ E_(b) 1717 E_(1a)E_(ii)E₄ AlkLE_(vii) E₄*E₅ E_(b) 1718 E_(1b)E_(ii)E₄ AlkLE_(vii) E₄*E₅ E_(b) 1719 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(vii) E₄*E₅ E_(b) 1720 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(vii) E₄*E₅ E_(b) 1721 E_(1a)E_(iii) AlkLE_(vii) E₄*E₅ E_(b) 1722 E_(1b)E_(iii) AlkLE_(vii) E₄*E₅ E_(b) 1723 E_(1a)E_(iii)E₄ AlkLE_(vii) E₄*E₅ E_(b) 1724 E_(1b)E_(iii)E₄ AlkLE_(vii) E₄*E₅ E_(b) 1725 E_(1a)E_(iv) AlkLE_(vii) E₄*E₅ E_(b) 1726 E_(1b)E_(iv) AlkLE_(vii) E₄*E₅ E_(b) 1727 E_(1a)E_(iv)E₄ AlkLE_(vii) E₄*E₅ E_(b) 1728 E_(1b)E_(iv)E₄ AlkLE_(vii) E₄*E₅ E_(b) 1729 E_(1a) E_(vii) E_(d) 1730 E_(1b) E_(vii) E_(d) 1731 E_(1a)E_(i) E_(vii) E_(d) 1732 E_(1b)E_(i) E_(vii) E_(d) 1733 E_(1a)E_(ii) E_(vii) E_(d) 1734 E_(1b)E_(ii) E_(vii) E_(d) 1735 E_(1a)E_(ii)E_(iib) E_(vii) E_(d) 1736 E_(1b)E_(ii)E_(iib) E_(vii) E_(d) 1737 E_(1a)E₄ E_(vii) E_(d) 1738 E_(1b)E₄ E_(vii) E_(d) 1739 E_(1a)E_(i)E₄ E_(vii) E_(d) 1740 E_(1b)E_(i)E₄ E_(vii) E_(d) 1741 E_(1a)E_(ii)E₄ E_(vii) E_(d) 1742 E_(1b)E_(ii)E₄ E_(vii) E_(d) 1743 E_(1a)E_(ii)E_(iib)E₄ E_(vii) E_(d) 1744 E_(1b)E_(ii)E_(iib)E₄ E_(vii) E_(d) 1745 E_(1a)E_(iii) E_(vii) E_(d) 1746 E_(1b)E_(iii) E_(vii) E_(d) 1747 E_(1a)E_(iii)E₄ E_(vii) E_(d) 1748 E_(1b)E_(iii)E₄ E_(vii) E_(d) 1749 E_(1a)E_(iv) E_(vii) E_(d) 1750 E_(1b)E_(iv) E_(vii) E_(d) 1751 E_(1a)E_(iv)E₄ E_(vii) E_(d) 1752 E_(1b)E_(iv)E₄ E_(vii) E_(d) 1753 E_(1a) E_(vii) E₄* E_(d) 1754 E_(1b) E_(vii) E₄* E_(d) 1755 E_(1a)E_(i) E_(vii) E₄* E_(d) 1756 E_(1b)E_(i) E_(vii) E₄* E_(d) 1757 E_(1a)E_(ii) E_(vii) E₄* E_(d) 1758 E_(1b)E_(ii) E_(vii) E₄* E_(d) 1759 E_(1a)E_(ii)E_(iib) E_(vii) E₄* E_(d) 1760 E_(1b)E_(ii)E_(iib) E_(vii) E₄* E_(d) 1761 E_(1a)E₄ E_(vii) E₄* E_(d) 1762 E_(1b)E₄ E_(vii) E₄* E_(d) 1763 E_(1a)E_(i)E₄ E_(vii) E₄* E_(d) 1764 E_(1b)E_(i)E₄ E_(vii) E₄* E_(d) 1765 E_(1a)E_(ii)E₄ E_(vii) E₄* E_(d) 1766 E_(1b)E_(ii)E₄ E_(vii) E₄* E_(d) 1767 E_(1a)E_(ii)E_(iib)E₄ E_(vii) E₄* E_(d) 1768 E_(1b)E_(ii)E_(iib)E₄ E_(vii) E₄* E_(d) 1769 E_(1a)E_(iii) E_(vii) E₄* E_(d) 1770 E_(1b)E_(iii) E_(vii) E₄* E_(d) 1771 E_(1a)E_(iii)E₄ E_(vii) E₄* E_(d) 1772 E_(1b)E_(iii)E₄ E_(vii) E₄* E_(d) 1773 E_(1a)E_(iv) E_(vii) E₄* E_(d) 1774 E_(1b)E_(iv) E_(vii) E₄* E_(d) 1775 E_(1a)E_(iv)E₄ E_(vii) E₄* E_(d) 1776 E_(1b)E_(iv)E₄ E_(vii) E₄* E_(d) 1777 E_(1a) E_(vii) E₅ E_(d) 1778 E_(1b) E_(vii) E₅ E_(d) 1779 E_(1a)E_(i) E_(vii) E₅ E_(d) 1780 E_(1b)E_(i) E_(vii) E₅ E_(d) 1781 E_(1a)E_(ii) E_(vii) E₅ E_(d) 1782 E_(1b)E_(ii) E_(vii) E₅ E_(d) 1783 E_(1a)E_(ii)E_(iib) E_(vii) E₅ E_(d) 1784 E_(1b)E_(ii)E_(iib) E_(vii) E₅ E_(d) 1785 E_(1a)E₄ E_(vii) E₅ E_(d) 1786 E_(1b)E₄ E_(vii) E₅ E_(d) 1787 E_(1a)E_(i)E₄ E_(vii) E₅ E_(d) 1788 E_(1b)E_(i)E₄ E_(vii) E₅ E_(d) 1789 E_(1a)E_(ii)E₄ E_(vii) E₅ E_(d) 1790 E_(1b)E_(ii)E₄ E_(vii) E₅ E_(d) 1791 E_(1a)E_(ii)E_(iib)E₄ E_(vii) E₅ E_(d) 1792 E_(1b)E_(ii)E_(iib)E₄ E_(vii) E₅ E_(d) 1793 E_(1a)E_(iii) E_(vii) E₅ E_(d) 1794 E_(1b)E_(iii) E_(vii) E₅ E_(d) 1795 E_(1a)E_(iii)E₄ E_(vii) E₅ E_(d) 1796 E_(1b)E_(iii)E₄ E_(vii) E₅ E_(d) 1797 E_(1a)E_(iv) E_(vii) E₅ E_(d) 1798 E_(1b)E_(iv) E_(vii) E₅ E_(d) 1799 E_(1a)E_(iv)E₄ E_(vii) E₅ E_(d) 1800 E_(1b)E_(iv)E₄ E_(vii) E₅ E_(d) 1801 E_(1a) E_(vii) E₄*E₅ E_(d) 1802 E_(1b) E_(vii) E₄*E₅ E_(d) 1803 E_(1a)E_(i) E_(vii) E₄*E₅ E_(d) 1804 E_(1b)E_(i) E_(vii) E₄*E₅ E_(d) 1805 E_(1a)E_(ii) E_(vii) E₄*E₅ E_(d) 1806 E_(1b)E_(ii) E_(vii) E₄*E₅ E_(d) 1807 E_(1a)E_(ii)E_(iib) E_(vii) E₄*E₅ E_(d) 1808 E_(1b)E_(ii)E_(iib) E_(vii) E₄*E₅ E_(d) 1809 E_(1a)E₄ E_(vii) E₄*E₅ E_(d) 1810 E_(1b)E₄ E_(vii) E₄*E₅ E_(d) 1811 E_(1a)E_(i)E₄ E_(vii) E₄*E₅ E_(d) 1812 E_(1b)E_(i)E₄ E_(vii) E₄*E₅ E_(d) 1813 E_(1a)E_(ii)E₄ E_(vii) E₄*E₅ E_(d) 1814 E_(1b)E_(ii)E₄ E_(vii) E₄*E₅ E_(d) 1815 E_(1a)E_(ii)E_(iib)E₄ E_(vii) E₄*E₅ E_(d) 1816 E_(1b)E_(ii)E_(iib)E₄ E_(vii) E₄*E₅ E_(d) 1817 E_(1a)E_(iii) E_(vii) E₄*E₅ E_(d) 1818 E_(1b)E_(iii) E_(vii) E₄*E₅ E_(d) 1819 E_(1a)E_(iii)E₄ E_(vii) E₄*E₅ E_(d) 1820 E_(1b)E_(iii)E₄ E_(vii) E₄*E₅ E_(d) 1821 E_(1a)E_(iv) E_(vii) E₄*E₅ E_(d) 1822 E_(1b)E_(iv) E_(vii) E₄*E₅ E_(d) 1823 E_(1a)E_(iv)E₄ E_(vii) E₄*E₅ E_(d) 1824 E_(1b)E_(iv)E₄ E_(vii) E₄*E₅ E_(d) 1825 E_(1a) AlkLE_(vii) E_(d) 1826 E_(1b) AlkLE_(vii) E_(d) 1827 E_(1a)E_(i) AlkLE_(vii) E_(d) 1828 E_(1b)E_(i) AlkLE_(vii) E_(d) 1829 E_(1a)E_(ii) AlkLE_(vii) E_(d) 1830 E_(1b)E_(ii) AlkLE_(vii) E_(d) 1831 E_(1a)E_(ii)E_(iib) AlkLE_(vii) E_(d) 1832 E_(1b)E_(ii)E_(iib) AlkLE_(vii) E_(d) 1833 E_(1a)E₄ AlkLE_(vii) E_(d) 1834 E_(1b)E₄ AlkLE_(vii) E_(d) 1835 E_(1a)E_(i)E₄ AlkLE_(vii) E_(d) 1836 E_(1b)E_(i)E₄ AlkLE_(vii) E_(d) 1837 E_(1a)E_(ii)E₄ AlkLE_(vii) E_(d) 1838 E_(1b)E_(ii)E₄ AlkLE_(vii) E_(d) 1839 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(vii) E_(d) 1840 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(vii) E_(d) 1841 E_(1a)E_(iii) AlkLE_(vii) E_(d) 1842 E_(1b)E_(iii) AlkLE_(vii) E_(d) 1843 E_(1a)E_(iii)E₄ AlkLE_(vii) E_(d) 1844 E_(1b)E_(iii)E₄ AlkLE_(vii) E_(d) 1845 E_(1a)E_(iv) AlkLE_(vii) E_(d) 1846 E_(1b)E_(iv) AlkLE_(vii) E_(d) 1847 E_(1a)E_(iv)E₄ AlkLE_(vii) E_(d) 1848 E_(1b)E_(iv)E₄ AlkLE_(vii) E_(d) 1849 E_(1a) AlkLE_(vii) E₄* E_(d) 1850 E_(1b) AlkLE_(vii) E₄* E_(d) 1851 E_(1a)E_(i) AlkLE_(vii) E₄* E_(d) 1852 E_(1b)E_(i) AlkLE_(vii) E₄* E_(d) 1853 E_(1a)E_(ii) AlkLE_(vii) E₄* E_(d) 1854 E_(1b)E_(ii) AlkLE_(vii) E₄* E_(d) 1855 E_(1a)E_(ii)E_(iib) AlkLE_(vii) E₄* E_(d) 1856 E_(1b)E_(ii)E_(iib) AlkLE_(vii) E₄* E_(d) 1857 E_(1a)E₄ AlkLE_(vii) E₄* E_(d) 1858 E_(1b)E₄ AlkLE_(vii) E₄* E_(d) 1859 E_(1a)E_(i)E₄ AlkLE_(vii) E₄* E_(d) 1860 E_(1b)E_(i)E₄ AlkLE_(vii) E₄* E_(d) 1861 E_(1a)E_(ii)E₄ AlkLE_(vii) E₄* E_(d) 1862 E_(1b)E_(ii)E₄ AlkLE_(vii) E₄* E_(d) 1863 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* E_(d) 1864 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* E_(d) 1865 E_(1a)E_(iii) AlkLE_(vii) E₄* E_(d) 1866 E_(1b)E_(iii) AlkLE_(vii) E₄* E_(d) 1867 E_(1a)E_(iii)E₄ AlkLE_(vii) E₄* E_(d) 1868 E_(1b)E_(iii)E₄ AlkLE_(vii) E₄* E_(d) 1869 E_(1a)E_(iv) AlkLE_(vii) E₄* E_(d) 1870 E_(1b)E_(iv) AlkLE_(vii) E₄* E_(d) 1871 E_(1a)E_(iv)E₄ AlkLE_(vii) E₄* E_(d) 1872 E_(1b)E_(iv)E₄ AlkLE_(vii) E₄* E_(d) 1873 E_(1a) AlkLE_(vii) E₅ E_(d) 1874 E_(1b) AlkLE_(vii) E₅ E_(d) 1875 E_(1a)E_(i) AlkLE_(vii) E₅ E_(d) 1876 E_(1b)E_(i) AlkLE_(vii) E₅ E_(d) 1877 E_(1a)E_(ii) AlkLE_(vii) E₅ E_(d) 1878 E_(1b)E_(ii) AlkLE_(vii) E₅ E_(d) 1879 E_(1a)E_(ii)E_(iib) AlkLE_(vii) E₅ E_(d) 1880 E_(1b)E_(ii)E_(iib) AlkLE_(vii) E₅ E_(d) 1881 E_(1a)E₄ AlkLE_(vii) E₅ E_(d) 1882 E_(1b)E₄ AlkLE_(vii) E₅ E_(d) 1883 E_(1a)E_(i)E₄ AlkLE_(vii) E₅ E_(d) 1884 E_(1b)E_(i)E₄ AlkLE_(vii) E₅ E_(d) 1885 E_(1a)E_(ii)E₄ AlkLE_(vii) E₅ E_(d) 1886 E_(1b)E_(ii)E₄ AlkLE_(vii) E₅ E_(d) 1887 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(vii) E₅ E_(d) 1888 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(vii) E₅ E_(d) 1889 E_(1a)E_(iii) AlkLE_(vii) E₅ E_(d) 1890 E_(1b)E_(iii) AlkLE_(vii) E₅ E_(d) 1891 E_(1a)E_(iii)E₄ AlkLE_(vii) E₅ E_(d) 1892 E_(1b)E_(iii)E₄ AlkLE_(vii) E₅ E_(d) 1893 E_(1a)E_(iv) AlkLE_(vii) E₅ E_(d) 1894 E_(1b)E_(iv) AlkLE_(vii) E₅ E_(d) 1895 E_(1a)E_(iv)E₄ AlkLE_(vii) E₅ E_(d) 1896 E_(1b)E_(iv)E₄ AlkLE_(vii) E₅ E_(d) 1897 E_(1a) AlkLE_(vii) E₄*E₅ E_(d) 1898 E_(1b) AlkLE_(vii) E₄*E₅ E_(d) 1899 E_(1a)E_(i) AlkLE_(vii) E₄*E₅ E_(d) 1900 E_(1b)E_(i) AlkLE_(vii) E₄*E₅ E_(d) 1901 E_(1a)E_(ii) AlkLE_(vii) E₄*E₅ E_(d) 1902 E_(1b)E_(ii) AlkLE_(vii) E₄*E₅ E_(d) 1903 E_(1a)E_(ii)E_(iib) AlkLE_(vii) E₄*E₅ E_(d) 1904 E_(1b)E_(ii)E_(iib) AlkLE_(vii) E₄*E₅ E_(d) 1905 E_(1a)E₄ AlkLE_(vii) E₄*E₅ E_(d) 1906 E_(1b)E₄ AlkLE_(vii) E₄*E₅ E_(d) 1907 E_(1a)E_(i)E₄ AlkLE_(vii) E₄*E₅ E_(d) 1908 E_(1b)E_(i)E₄ AlkLE_(vii) E₄*E₅ E_(d) 1909 E_(1a)E_(ii)E₄ AlkLE_(vii) E₄*E₅ E_(d) 1910 E_(1b)E_(ii)E₄ AlkLE_(vii) E₄*E₅ E_(d) 1911 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(vii) E₄*E₅ E_(d) 1912 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(vii) E₄*E₅ E_(d) 1913 E_(1a)E_(iii) AlkLE_(vii) E₄*E₅ E_(d) 1914 E_(1b)E_(iii) AlkLE_(vii) E₄*E₅ E_(d) 1915 E_(1a)E_(iii)E₄ AlkLE_(vii) E₄*E₅ E_(d) 1916 E_(1b)E_(iii)E₄ AlkLE_(vii) E₄*E₅ E_(d) 1917 E_(1a)E_(iv) AlkLE_(vii) E₄*E₅ E_(d) 1918 E_(1b)E_(iv) AlkLE_(vii) E₄*E₅ E_(d) 1919 E_(1a)E_(iv)E₄ AlkLE_(vii) E₄*E₅ E_(d) 1920 E_(1b)E_(iv)E₄ AlkLE_(vii) E₄*E₅ E_(d) 1921 E_(1a) E_(vii) E_(e) 1922 E_(1b) E_(vii) E_(e) 1923 E_(1a)E_(i) E_(vii) E_(e) 1924 E_(1b)E_(i) E_(vii) E_(e) 1925 E_(1a)E_(ii) E_(vii) E_(e) 1926 E_(1b)E_(ii) E_(vii) E_(e) 1927 E_(1a)E_(ii)E_(iib) E_(vii) E_(e) 1928 E_(1b)E_(ii)E_(iib) E_(vii) E_(e) 1929 E_(1a)E₄ E_(vii) E_(e) 1930 E_(1b)E₄ E_(vii) E_(e) 1931 E_(1a)E_(i)E₄ E_(vii) E_(e) 1932 E_(1b)E_(i)E₄ E_(vii) E_(e) 1933 E_(1a)E_(ii)E₄ E_(vii) E_(e) 1934 E_(1b)E_(ii)E₄ E_(vii) E_(e) 1935 E_(1a)E_(ii)E_(iib)E₄ E_(vii) E_(e) 1936 E_(1b)E_(ii)E_(iib)E₄ E_(vii) E_(e) 1937 E_(1a)E_(iii) E_(vii) E_(e) 1938 E_(1b)E_(iii) E_(vii) E_(e) 1939 E_(1a)E_(iii)E₄ E_(vii) E_(e) 1940 E_(1b)E_(iii)E₄ E_(vii) E_(e) 1941 E_(1a)E_(iv) E_(vii) E_(e) 1942 E_(1b)E_(iv) E_(vii) E_(e) 1943 E_(1a)E_(iv)E₄ E_(vii) E_(e) 1944 E_(1b)E_(iv)E₄ E_(vii) E_(e) 1945 E_(1a) E_(vii) E₄* E_(e) 1946 E_(1b) E_(vii) E₄* E_(e) 1947 E_(1a)E_(i) E_(vii) E₄* E_(e) 1948 E_(1b)E_(i) E_(vii) E₄* E_(e) 1949 E_(1a)E_(ii) E_(vii) E₄* E_(e) 1950 E_(1b)E_(ii) E_(vii) E₄* E_(e) 1951 E_(1a)E_(ii)E_(iib) E_(vii) E₄* E_(e) 1952 E_(1b)E_(ii)E_(iib) E_(vii) E₄* E_(e) 1953 E_(1a)E₄ E_(vii) E₄* E_(e) 1954 E_(1b)E₄ E_(vii) E₄* E_(e) 1955 E_(1a)E_(i)E₄ E_(vii) E₄* E_(e) 1956 E_(1b)E_(i)E₄ E_(vii) E₄* E_(e) 1957 E_(1a)E_(ii)E₄ E_(vii) E₄* E_(e) 1958 E_(1b)E_(ii)E₄ E_(vii) E₄* E_(e) 1959 E_(1a)E_(ii)E_(iib)E₄ E_(vii) E₄* E_(e) 1960 E_(1b)E_(ii)E_(iib)E₄ E_(vii) E₄* E_(e) 1961 E_(1a)E_(iii) E_(vii) E₄* E_(e) 1962 E_(1b)E_(iii) E_(vii) E₄* E_(e) 1963 E_(1a)E_(iii)E₄ E_(vii) E₄* E_(e) 1964 E_(1b)E_(iii)E₄ E_(vii) E₄* E_(e) 1965 E_(1a)E_(iv) E_(vii) E₄* E_(e) 1966 E_(1b)E_(iv) E_(vii) E₄* E_(e) 1967 E_(1a)E_(iv)E₄ E_(vii) E₄* E_(e) 1968 E_(1b)E_(iv)E₄ E_(vii) E₄* E_(e) 1969 E_(1a) E_(vii) E₅ E_(e) 1970 E_(1b) E_(vii) E₅ E_(e) 1971 E_(1a)E_(i) E_(vii) E₅ E_(e) 1972 E_(1b)E_(i) E_(vii) E₅ E_(e) 1973 E_(1a)E_(ii) E_(vii) E₅ E_(e) 1974 E_(1b)E_(ii) E_(vii) E₅ E_(e) 1975 E_(1a)E_(ii)E_(iib) E_(vii) E₅ E_(e) 1976 E_(1b)E_(ii)E_(iib) E_(vii) E₅ E_(e) 1977 E_(1a)E₄ E_(vii) E₅ E_(e) 1978 E_(1b)E₄ E_(vii) E₅ E_(e) 1979 E_(1a)E_(i)E₄ E_(vii) E₅ E_(e) 1980 E_(1b)E_(i)E₄ E_(vii) E₅ E_(e) 1981 E_(1a)E_(ii)E₄ E_(vii) E₅ E_(e) 1982 E_(1b)E_(ii)E₄ E_(vii) E₅ E_(e) 1983 E_(1a)E_(ii)E_(iib)E₄ E_(vii) E₅ E_(e) 1984 E_(1b)E_(ii)E_(iib)E₄ E_(vii) E₅ E_(e) 1985 E_(1a)E_(iii) E_(vii) E₅ E_(e) 1986 E_(1b)E_(iii) E_(vii) E₅ E_(e) 1987 E_(1a)E_(iii)E₄ E_(vii) E₅ E_(e) 1988 E_(1b)E_(iii)E₄ E_(vii) E₅ E_(e) 1989 E_(1a)E_(iv) E_(vii) E₅ E_(e) 1990 E_(1b)E_(iv) E_(vii) E₅ E_(e) 1991 E_(1a)E_(iv)E₄ E_(vii) E₅ E_(e) 1992 E_(1b)E_(iv)E₄ E_(vii) E₅ E_(e) 1993 E_(1a) E_(vii) E₄*E₅ E_(e) 1994 E_(1b) E_(vii) E₄*E₅ E_(e) 1995 E_(1a)E_(i) E_(vii) E₄*E₅ E_(e) 1996 E_(1b)E_(i) E_(vii) E₄*E₅ E_(e) 1997 E_(1a)E_(ii) E_(vii) E₄*E₅ E_(e) 1998 E_(1b)E_(ii) E_(vii) E₄*E₅ E_(e) 1999 E_(1a)E_(ii)E_(iib) E_(vii) E₄*E₅ E_(e) 2000 E_(1b)E_(ii)E_(iib) E_(vii) E₄*E₅ E_(e) 2001 E_(1a)E₄ E_(vii) E₄*E₅ E_(e) 2002 E_(1b)E₄ E_(vii) E₄*E₅ E_(e) 2003 E_(1a)E_(i)E₄ E_(vii) E₄*E₅ E_(e) 2004 E_(1b)E_(i)E₄ E_(vii) E₄*E₅ E_(e) 2005 E_(1a)E_(ii)E₄ E_(vii) E₄*E₅ E_(e) 2006 E_(1b)E_(ii)E₄ E_(vii) E₄*E₅ E_(e) 2007 E_(1a)E_(ii)E_(iib)E₄ E_(vii) E₄*E₅ E_(e) 2008 E_(1b)E_(ii)E_(iib)E₄ E_(vii) E₄*E₅ E_(e) 2009 E_(1a)E_(iii) E_(vii) E₄*E₅ E_(e) 2010 E_(1b)E_(iii) E_(vii) E₄*E₅ E_(e) 2011 E_(1a)E_(iii)E₄ E_(vii) E₄*E₅ E_(e) 2012 E_(1b)E_(iii)E₄ E_(vii) E₄*E₅ E_(e) 2013 E_(1a)E_(iv) E_(vii) E₄*E₅ E_(e) 2014 E_(1b)E_(iv) E_(vii) E₄*E₅ E_(e) 2015 E_(1a)E_(iv)E₄ E_(vii) E₄*E₅ E_(e) 2016 E_(1b)E_(iv)E₄ E_(vii) E₄*E₅ E_(e) 2017 E_(1a) AlkLE_(vii) E_(e) 2018 E_(1b) AlkLE_(vii) E_(e) 2019 E_(1a)E_(i) AlkLE_(vii) E_(e) 2020 E_(1b)E_(i) AlkLE_(vii) E_(e) 2021 E_(1a)E_(ii) AlkLE_(vii) E_(e) 2022 E_(1b)E_(ii) AlkLE_(vii) E_(e) 2023 E_(1a)E_(ii)E_(iib) AlkLE_(vii) E_(e) 2024 E_(1b)E_(ii)E_(iib) AlkLE_(vii) E_(e) 2025 E_(1a)E₄ AlkLE_(vii) E_(e) 2026 E_(1b)E₄ AlkLE_(vii) E_(e) 2027 E_(1a)E_(i)E₄ AlkLE_(vii) E_(e) 2028 E_(1b)E_(i)E₄ AlkLE_(vii) E_(e) 2029 E_(1a)E_(ii)E₄ AlkLE_(vii) E_(e) 2030 E_(1b)E_(ii)E₄ AlkLE_(vii) E_(e) 2031 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(vii) E_(e) 2032 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(vii) E_(e) 2033 E_(1a)E_(iii) AlkLE_(vii) E_(e) 2034 E_(1b)E_(iii) AlkLE_(vii) E_(e) 2035 E_(1a)E_(iii)E₄ AlkLE_(vii) E_(e) 2036 E_(1b)E_(iii)E₄ AlkLE_(vii) E_(e) 2037 E_(1a)E_(iv) AlkLE_(vii) E_(e) 2038 E_(1b)E_(iv) AlkLE_(vii) E_(e) 2039 E_(1a)E_(iv)E₄ AlkLE_(vii) E_(e) 2040 E_(1b)E_(iv)E₄ AlkLE_(vii) E_(e) 2041 E_(1a) AlkLE_(vii) E₄* E_(e) 2042 E_(1b) AlkLE_(vii) E₄* E_(e) 2043 E_(1a)E_(i) AlkLE_(vii) E₄* E_(e) 2044 E_(1b)E_(i) AlkLE_(vii) E₄* E_(e) 2045 E_(1a)E_(ii) AlkLE_(vii) E₄* E_(e) 2046 E_(1b)E_(ii) AlkLE_(vii) E₄* E_(e) 2047 E_(1a)E_(ii)E_(iib) AlkLE_(vii) E₄* E_(e) 2048 E_(1b)E_(ii)E_(iib) AlkLE_(vii) E₄* E_(e) 2049 E_(1a)E₄ AlkLE_(vii) E₄* E_(e) 2050 E_(1b)E₄ AlkLE_(vii) E₄* E_(e) 2051 E_(1a)E_(i)E₄ AlkLE_(vii) E₄* E_(e) 2052 E_(1b)E_(i)E₄ AlkLE_(vii) E₄* E_(e) 2053 E_(1a)E_(ii)E₄ AlkLE_(vii) E₄* E_(e) 2054 E_(1b)E_(ii)E₄ AlkLE_(vii) E₄* E_(e) 2055 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* E_(e) 2056 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* E_(e) 2057 E_(1a)E_(iii) AlkLE_(vii) E₄* E_(e) 2058 E_(1b)E_(iii) AlkLE_(vii) E₄* E_(e) 2059 E_(1a)E_(iii)E₄ AlkLE_(vii) E₄* E_(e) 2060 E_(1b)E_(iii)E₄ AlkLE_(vii) E₄* E_(e) 2061 E_(1a)E_(iv) AlkLE_(vii) E₄* E_(e) 2062 E_(1b)E_(iv) AlkLE_(vii) E₄* E_(e) 2063 E_(1a)E_(iv)E₄ AlkLE_(vii) E₄* E_(e) 2064 E_(1b)E_(iv)E₄ AlkLE_(vii) E₄* E_(e) 2065 E_(1a) AlkLE_(vii) E₅ E_(e) 2066 E_(1b) AlkLE_(vii) E₅ E_(e) 2067 E_(1a)E_(i) AlkLE_(vii) E₅ E_(e) 2068 E_(1b)E_(i) AlkLE_(vii) E₅ E_(e) 2069 E_(1a)E_(ii) AlkLE_(vii) E₅ E_(e) 2070 E_(1b)E_(ii) AlkLE_(vii) E₅ E_(e) 2071 E_(1a)E_(ii)E_(iib) AlkLE_(vii) E₅ E_(e) 2072 E_(1b)E_(ii)E_(iib) AlkLE_(vii) E₅ E_(e) 2073 E_(1a)E₄ AlkLE_(vii) E₅ E_(e) 2074 E_(1b)E₄ AlkLE_(vii) E₅ E_(e) 2075 E_(1a)E_(i)E₄ AlkLE_(vii) E₅ E_(e) 2076 E_(1b)E_(i)E₄ AlkLE_(vii) E₅ E_(e) 2077 E_(1a)E_(ii)E₄ AlkLE_(vii) E₅ E_(e) 2078 E_(1b)E_(ii)E₄ AlkLE_(vii) E₅ E_(e) 2079 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(vii) E₅ E_(e) 2080 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(vii) E₅ E_(e) 2081 E_(1a)E_(iii) AlkLE_(vii) E₅ E_(e) 2082 E_(1b)E_(iii) AlkLE_(vii) E₅ E_(e) 2083 E_(1a)E_(iii)E₄ AlkLE_(vii) E₅ E_(e) 2084 E_(1b)E_(iii)E₄ AlkLE_(vii) E₅ E_(e) 2085 E_(1a)E_(iv) AlkLE_(vii) E₅ E_(e) 2086 E_(1b)E_(iv) AlkLE_(vii) E₅ E_(e) 2087 E_(1a)E_(iv)E₄ AlkLE_(vii) E₅ E_(e) 2088 E_(1b)E_(iv)E₄ AlkLE_(vii) E₅ E_(e) 2089 E_(1a) AlkLE_(vii) E₄*E₅ E_(e) 2090 E_(1b) AlkLE_(vii) E₄*E₅ E_(e) 2091 E_(1a)E_(i) AlkLE_(vii) E₄*E₅ E_(e) 2092 E_(1b)E_(i) AlkLE_(vii) E₄*E₅ E_(e) 2093 E_(1a)E_(ii) AlkLE_(vii) E₄*E₅ E_(e) 2094 E_(1b)E_(ii) AlkLE_(vii) E₄*E₅ E_(e) 2095 E_(1a)E_(ii)E_(iib) AlkLE_(vii) E₄*E₅ E_(e) 2096 E_(1b)E_(ii)E_(iib) AlkLE_(vii) E₄*E₅ E_(e) 2097 E_(1a)E₄ AlkLE_(vii) E₄*E₅ E_(e) 2098 E_(1b)E₄ AlkLE_(vii) E₄*E₅ E_(e) 2099 E_(1a)E_(i)E₄ AlkLE_(vii) E₄*E₅ E_(e) 2100 E_(1b)E_(i)E₄ AlkLE_(vii) E₄*E₅ E_(e) 2101 E_(1a)E_(ii)E₄ AlkLE_(vii) E₄*E₅ E_(e) 2102 E_(1b)E_(ii)E₄ AlkLE_(vii) E₄*E₅ E_(e) 2103 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(vii) E₄*E₅ E_(e) 2104 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(vii) E₄*E₅ E_(e) 2105 E_(1a)E_(iii) AlkLE_(vii) E₄*E₅ E_(e) 2106 E_(1b)E_(iii) AlkLE_(vii) E₄*E₅ E_(e) 2107 E_(1a)E_(iii)E₄ AlkLE_(vii) E₄*E₅ E_(e) 2108 E_(1b)E_(iii)E₄ AlkLE_(vii) E₄*E₅ E_(e) 2109 E_(1a)E_(iv) AlkLE_(vii) E₄*E₅ E_(e) 2110 E_(1b)E_(iv) AlkLE_(vii) E₄*E₅ E_(e) 2111 E_(1a)E_(iv)E₄ AlkLE_(vii) E₄*E₅ E_(e) 2112 E_(1b)E_(iv)E₄ AlkLE_(vii) E₄*E₅ E_(e) 2113 E_(1a) E_(vii) E_(f) 2114 E_(1b) E_(vii) E_(f) 2115 E_(1a)E_(i) E_(vii) E_(f) 2116 E_(1b)E_(i) E_(vii) E_(f) 2117 E_(1a)E_(ii) E_(vii) E_(f) 2118 E_(1b)E_(ii) E_(vii) E_(f) 2119 E_(1a)E_(ii)E_(iib) E_(vii) E_(f) 2120 E_(1b)E_(ii)E_(iib) E_(vii) E_(f) 2121 E_(1a)E₄ E_(vii) E_(f) 2122 E_(1b)E₄ E_(vii) E_(f) 2123 E_(1a)E_(i)E₄ E_(vii) E_(f) 2124 E_(1b)E_(i)E₄ E_(vii) E_(f) 2125 E_(1a)E_(ii)E₄ E_(vii) E_(f) 2126 E_(1b)E_(ii)E₄ E_(vii) E_(f) 2127 E_(1a)E_(ii)E_(iib)E₄ E_(vii) E_(f) 2128 E_(1b)E_(ii)E_(iib)E₄ E_(vii) E_(f) 2129 E_(1a)E_(iii) E_(vii) E_(f) 2130 E_(1b)E_(iii) E_(vii) E_(f) 2131 E_(1a)E_(iii)E₄ E_(vii) E_(f) 2132 E_(1b)E_(iii)E₄ E_(vii) E_(f) 2133 E_(1a)E_(iv) E_(vii) E_(f) 2134 E_(1b)E_(iv) E_(vii) E_(f) 2135 E_(1a)E_(iv)E₄ E_(vii) E_(f) 2136 E_(1b)E_(iv)E₄ E_(vii) E_(f) 2137 E_(1a) E_(vii) E₄* E_(f) 2138 E_(1b) E_(vii) E₄* E_(f) 2139 E_(1a)E_(i) E_(vii) E₄* E_(f) 2140 E_(1b)E_(i) E_(vii) E₄* E_(f) 2141 E_(1a)E_(ii) E_(vii) E₄* E_(f) 2142 E_(1b)E_(ii) E_(vii) E₄* E_(f) 2143 E_(1a)E_(ii)E_(iib) E_(vii) E₄* E_(f) 2144 E_(1b)E_(ii)E_(iib) E_(vii) E₄* E_(f) 2145 E_(1a)E₄ E_(vii) E₄* E_(f) 2146 E_(1b)E₄ E_(vii) E₄* E_(f) 2147 E_(1a)E_(i)E₄ E_(vii) E₄* E_(f) 2148 E_(1b)E_(i)E₄ E_(vii) E₄* E_(f) 2149 E_(1a)E_(ii)E₄ E_(vii) E₄* E_(f) 2150 E_(1b)E_(ii)E₄ E_(vii) E₄* E_(f) 2151 E_(1a)E_(ii)E_(iib)E₄ E_(vii) E₄* E_(f) 2152 E_(1b)E_(ii)E_(iib)E₄ E_(vii) E₄* E_(f) 2153 E_(1a)E_(iii) E_(vii) E₄* E_(f) 2154 E_(1b)E_(iii) E_(vii) E₄* E_(f) 2155 E_(1a)E_(iii)E₄ E_(vii) E₄* E_(f) 2156 E_(1b)E_(iii)E₄ E_(vii) E₄* E_(f) 2157 E_(1a)E_(iv) E_(vii) E₄* E_(f) 2158 E_(1b)E_(iv) E_(vii) E₄* E_(f) 2159 E_(1a)E_(iv)E₄ E_(vii) E₄* E_(f) 2160 E_(1b)E_(iv)E₄ E_(vii) E₄* E_(f) 2161 E_(1a) E_(vii) E₅ E_(f) 2162 E_(1b) E_(vii) E₅ E_(f) 2163 E_(1a)E_(i) E_(vii) E₅ E_(f) 2164 E_(1b)E_(i) E_(vii) E₅ E_(f) 2165 E_(1a)E_(ii) E_(vii) E₅ E_(f) 2166 E_(1b)E_(ii) E_(vii) E₅ E_(f) 2167 E_(1a)E_(ii)E_(iib) E_(vii) E₅ E_(f) 2168 E_(1b)E_(ii)E_(iib) E_(vii) E₅ E_(f) 2169 E_(1a)E₄ E_(vii) E₅ E_(f) 2170 E_(1b)E₄ E_(vii) E₅ E_(f) 2171 E_(1a)E_(i)E₄ E_(vii) E₅ E_(f) 2172 E_(1b)E_(i)E₄ E_(vii) E₅ E_(f) 2173 E_(1a)E_(ii)E₄ E_(vii) E₅ E_(f) 2174 E_(1b)E_(ii)E₄ E_(vii) E₅ E_(f) 2175 E_(1a)E_(ii)E_(iib)E₄ E_(vii) E₅ E_(f) 2176 E_(1b)E_(ii)E_(iib)E₄ E_(vii) E₅ E_(f) 2177 E_(1a)E_(iii) E_(vii) E₅ E_(f) 2178 E_(1b)E_(iii) E_(vii) E₅ E_(f) 2179 E_(1a)E_(iii)E₄ E_(vii) E₅ E_(f) 2180 E_(1b)E_(iii)E₄ E_(vii) E₅ E_(f) 2181 E_(1a)E_(iv) E_(vii) E₅ E_(f) 2182 E_(1b)E_(iv) E_(vii) E₅ E_(f) 2183 E_(1a)E_(iv)E₄ E_(vii) E₅ E_(f) 2184 E_(1b)E_(iv)E₄ E_(vii) E₅ E_(f) 2185 E_(1a) E_(vii) E₄*E₅ E_(f) 2186 E_(1b) E_(vii) E₄*E₅ E_(f) 2187 E_(1a)E_(i) E_(vii) E₄*E₅ E_(f) 2188 E_(1b)E_(i) E_(vii) E₄*E₅ E_(f) 2189 E_(1a)E_(ii) E_(vii) E₄*E₅ E_(f) 2190 E_(1b)E_(ii) E_(vii) E₄*E₅ E_(f) 2191 E_(1a)E_(ii)E_(iib) E_(vii) E₄*E₅ E_(f) 2192 E_(1b)E_(ii)E_(iib) E_(vii) E₄*E₅ E_(f) 2193 E_(1a)E₄ E_(vii) E₄*E₅ E_(f) 2194 E_(1b)E₄ E_(vii) E₄*E₅ E_(f) 2195 E_(1a)E_(i)E₄ E_(vii) E₄*E₅ E_(f) 2196 E_(1b)E_(i)E₄ E_(vii) E₄*E₅ E_(f) 2197 E_(1a)E_(ii)E₄ E_(vii) E₄*E₅ E_(f) 2198 E_(1b)E_(ii)E₄ E_(vii) E₄*E₅ E_(f) 2199 E_(1a)E_(ii)E_(iib)E₄ E_(vii) E₄*E₅ E_(f) 2200 E_(1b)E_(ii)E_(iib)E₄ E_(vii) E₄*E₅ E_(f) 2201 E_(1a)E_(iii) E_(vii) E₄*E₅ E_(f) 2202 E_(1b)E_(iii) E_(vii) E₄*E₅ E_(f) 2203 E_(1a)E_(iii)E₄ E_(vii) E₄*E₅ E_(f) 2204 E_(1b)E_(iii)E₄ E_(vii) E₄*E₅ E_(f) 2205 E_(1a)E_(iv) E_(vii) E₄*E₅ E_(f) 2206 E_(1b)E_(iv) E_(vii) E₄*E₅ E_(f) 2207 E_(1a)E_(iv)E₄ E_(vii) E₄*E₅ E_(f) 2208 E_(1b)E_(iv)E₄ E_(vii) E₄*E₅ E_(f) 2209 E_(1a) AlkLE_(vii) E_(f) 2210 E_(1b) AlkLE_(vii) E_(f) 2211 E_(1a)E_(i) AlkLE_(vii) E_(f) 2212 E_(1b)E_(i) AlkLE_(vii) E_(f) 2213 E_(1a)E_(ii) AlkLE_(vii) E_(f) 2214 E_(1b)E_(ii) AlkLE_(vii) E_(f) 2215 E_(1a)E_(ii)E_(iib) AlkLE_(vii) E_(f) 2216 E_(1b)E_(ii)E_(iib) AlkLE_(vii) E_(f) 2217 E_(1a)E₄ AlkLE_(vii) E_(f) 2218 E_(1b)E₄ AlkLE_(vii) E_(f) 2219 E_(1a)E_(i)E₄ AlkLE_(vii) E_(f) 2220 E_(1b)E_(i)E₄ AlkLE_(vii) E_(f) 2221 E_(1a)E_(ii)E₄ AlkLE_(vii) E_(f) 2222 E_(1b)E_(ii)E₄ AlkLE_(vii) E_(f) 2223 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(vii) E_(f) 2224 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(vii) E_(f) 2225 E_(1a)E_(iii) AlkLE_(vii) E_(f) 2226 E_(1b)E_(iii) AlkLE_(vii) E_(f) 2227 E_(1a)E_(iii)E₄ AlkLE_(vii) E_(f) 2228 E_(1b)E_(iii)E₄ AlkLE_(vii) E_(f) 2229 E_(1a)E_(iv) AlkLE_(vii) E_(f) 2230 E_(1b)E_(iv) AlkLE_(vii) E_(f) 2231 E_(1a)E_(iv)E₄ AlkLE_(vii) E_(f) 2232 E_(1b)E_(iv)E₄ AlkLE_(vii) E_(f) 2233 E_(1a) AlkLE_(vii) E₄* E_(f) 2234 E_(1b) AlkLE_(vii) E₄* E_(f) 2235 E_(1a)E_(i) AlkLE_(vii) E₄* E_(f) 2236 E_(1b)E_(i) AlkLE_(vii) E₄* E_(f) 2237 E_(1a)E_(ii) AlkLE_(vii) E₄* E_(f) 2238 E_(1b)E_(ii) AlkLE_(vii) E₄* E_(f) 2239 E_(1a)E_(ii)E_(iib) AlkLE_(vii) E₄* E_(f) 2240 E_(1b)E_(ii)E_(iib) AlkLE_(vii) E₄* E_(f) 2241 E_(1a)E₄ AlkLE_(vii) E₄* E_(f) 2242 E_(1b)E₄ AlkLE_(vii) E₄* E_(f) 2243 E_(1a)E_(i)E₄ AlkLE_(vii) E₄* E_(f) 2244 E_(1b)E_(i)E₄ AlkLE_(vii) E₄* E_(f) 2245 E_(1a)E_(ii)E₄ AlkLE_(vii) E₄* E_(f) 2246 E_(1b)E_(ii)E₄ AlkLE_(vii) E₄* E_(f) 2247 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* E_(f) 2248 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* E_(f) 2249 E_(1a)E_(iii) AlkLE_(vii) E₄* E_(f) 2250 E_(1b)E_(iii) AlkLE_(vii) E₄* E_(f) 2251 E_(1a)E_(iii)E₄ AlkLE_(vii) E₄* E_(f) 2252 E_(1b)E_(iii)E₄ AlkLE_(vii) E₄* E_(f) 2253 E_(1a)E_(iv) AlkLE_(vii) E₄* E_(f) 2254 E_(1b)E_(iv) AlkLE_(vii) E₄* E_(f) 2255 E_(1a)E_(iv)E₄ AlkLE_(vii) E₄* E_(f) 2256 E_(1b)E_(iv)E₄ AlkLE_(vii) E₄* E_(f) 2257 E_(1a) AlkLE_(vii) E₅ E_(f) 2258 E_(1b) AlkLE_(vii) E₅ E_(f) 2259 E_(1a)E_(i) AlkLE_(vii) E₅ E_(f) 2260 E_(1b)E_(i) AlkLE_(vii) E₅ E_(f) 2261 E_(1a)E_(ii) AlkLE_(vii) E₅ E_(f) 2262 E_(1b)E_(ii) AlkLE_(vii) E₅ E_(f) 2263 E_(1a)E_(ii)E_(iib) AlkLE_(vii) E₅ E_(f) 2264 E_(1b)E_(ii)E_(iib) AlkLE_(vii) E₅ E_(f) 2265 E_(1a)E₄ AlkLE_(vii) E₅ E_(f) 2266 E_(1b)E₄ AlkLE_(vii) E₅ E_(f) 2267 E_(1a)E_(i)E₄ AlkLE_(vii) E₅ E_(f) 2268 E_(1b)E_(i)E₄ AlkLE_(vii) E₅ E_(f) 2269 E_(1a)E_(ii)E₄ AlkLE_(vii) E₅ E_(f) 2270 E_(1b)E_(ii)E₄ AlkLE_(vii) E₅ E_(f) 2271 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(vii) E₅ E_(f) 2272 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(vii) E₅ E_(f) 2273 E_(1a)E_(iii) AlkLE_(vii) E₅ E_(f) 2274 E_(1b)E_(iii) AlkLE_(vii) E₅ E_(f) 2275 E_(1a)E_(iii)E₄ AlkLE_(vii) E₅ E_(f) 2276 E_(1b)E_(iii)E₄ AlkLE_(vii) E₅ E_(f) 2277 E_(1a)E_(iv) AlkLE_(vii) E₅ E_(f) 2278 E_(1b)E_(iv) AlkLE_(vii) E₅ E_(f) 2279 E_(1a)E_(iv)E₄ AlkLE_(vii) E₅ E_(f) 2280 E_(1b)E_(iv)E₄ AlkLE_(vii) E₅ E_(f) 2281 E_(1a) AlkLE_(vii) E₄*E₅ E_(f) 2282 E_(1b) AlkLE_(vii) E₄*E₅ E_(f) 2283 E_(1a)E_(i) AlkLE_(vii) E₄*E₅ E_(f) 2284 E_(1b)E_(i) AlkLE_(vii) E₄*E₅ E_(f) 2285 E_(1a)E_(ii) AlkLE_(vii) E₄*E₅ E_(f) 2286 E_(1b)E_(ii) AlkLE_(vii) E₄*E₅ E_(f) 2287 E_(1a)E_(ii)E_(iib) AlkLE_(vii) E₄*E₅ E_(f) 2288 E_(1b)E_(ii)E_(iib) AlkLE_(vii) E₄*E₅ E_(f) 2289 E_(1a)E₄ AlkLE_(vii) E₄*E₅ E_(f) 2290 E_(1b)E₄ AlkLE_(vii) E₄*E₅ E_(f) 2291 E_(1a)E_(i)E₄ AlkLE_(vii) E₄*E₅ E_(f) 2292 E_(1b)E_(i)E₄ AlkLE_(vii) E₄*E₅ E_(f) 2293 E_(1a)E_(ii)E₄ AlkLE_(vii) E₄*E₅ E_(f) 2294 E_(1b)E_(ii)E₄ AlkLE_(vii) E₄*E₅ E_(f) 2295 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(vii) E₄*E₅ E_(f) 2296 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(vii) E₄*E₅ E_(f) 2297 E_(1a)E_(iii) AlkLE_(vii) E₄*E₅ E_(f) 2298 E_(1b)E_(iii) AlkLE_(vii) E₄*E₅ E_(f) 2299 E_(1a)E_(iii)E₄ AlkLE_(vii) E₄*E₅ E_(f) 2300 E_(1b)E_(iii)E₄ AlkLE_(vii) E₄*E₅ E_(f) 2301 E_(1a)E_(iv) AlkLE_(vii) E₄*E₅ E_(f) 2302 E_(1b)E_(iv) AlkLE_(vii) E₄*E₅ E_(f) 2303 E_(1a)E_(iv)E₄ AlkLE_(vii) E₄*E₅ E_(f) 2304 E_(1b)E_(iv)E₄ AlkLE_(vii) E₄*E₅ E_(f)

Microorganisms quite especially preferred according to the invention (abbreviated as MO) are outstandingly suitable for the production of ω-carboxycarboxylic acids and have increased or decreased enzyme activities (abbreviated as E) described in the following table, where these can in addition advantageously be combined with an increased enzyme activity compared to the wild type of the microorganism, which is described for the 3-ketoacyl-ACP (Acyl Carrrier Protein) synthase III (EC 2.3.1.41), in particular that from plants, preferably that from plants the seeds whereof contain fatty acids with alkyl residues shorter than 14 C atoms, and particularly preferably that from plants of the genera Cuphea, Elaeis, Cocos, Umbellularia and Cinnamomum and gene products selected from AccA, AccB, AccC, AccD, AceE, AceF, Lpd, AcpP, FabA, FabB, FabD, FabF, FabG, FabH, Fabl, FabZ, PanD, PanK, UdhA, PntA or PntB.

Any combinations of at least two of these enzyme activities can advantageously be increased.

In addition, moreover, it can be advantageous if the microorganism is provided with a lower enzyme activity compared to the wild type of the microorganism, which is described for the gene products selected from TdcE, PflA, PflB, PflC, PflD, PoxB, YgfG, AckA, AckB, TdcD, Pta, LdhA, AdhE, MgsA, FdnG, FdnH, FdnI, FdhF, FdoG, FdoH, FdoI, PrpC, PrpD, PrpF, PrpB, TdcD, Pdc, PorA, PorB, PorC, PorD, AlsS, IlvB, IlvM, IlvN, IlvG, IlyI, IlvH, AlsD, ButB, Thl, ThlA, ThlB, PhaA, PhaB, Crt, BdhA, BdhB, Adc, Adh, CtfB, AtoA, AtoD, LdhL, GltA, FabR, FhuA, Dld, LldA or LldP, singly or in any combination.

MO E increased E decreased 1 E_(1a) 2 E_(1b) 3 E_(1a)E₅ 4 E_(1b)E₅ 5 E_(1a)E_(i) 6 E_(1b)E_(i) 7 E_(1a)E_(ii) 8 E_(1b)E_(ii) 9 E_(1a)E_(ii)E_(iib) 10 E_(1b)E_(ii)E_(iib) 11 E_(1a)E₅E_(i) 12 E_(1b)E₅E_(i) 13 E_(1a)E₅E_(ii) 14 E_(1b)E₅E_(ii) 15 E_(1a)E₅E_(ii)E_(iib) 16 E_(1b)E₅E_(ii)E_(iib) 17 E_(1a)E₄ 18 E_(1b)E₄ 19 E_(1a)E₅E₄ 20 E_(1b)E₅E₄ 21 E_(1a)E_(i)E₄ 22 E_(1b)E_(i)E₄ 23 E_(1a)E_(ii)E₄ 24 E_(1b)E_(ii)E₄ 25 E_(1a)E_(ii)E_(iib)E₄ 26 E_(1b)E_(ii)E_(iib)E₄ 27 E_(1a)E₅E_(i)E₄ 28 E_(1b)E₅E_(i)E₄ 29 E_(1a)E₅E_(ii)E₄ 30 E_(1b)E₅E_(ii)E₄ 31 E_(1a)E₅E_(ii)E_(iib)E₄ 32 E_(1b)E₅E_(ii)E_(iib)E₄ 33 E_(1a)E_(iii) 34 E_(1b)E_(iii) 35 E_(1a)E₅E_(iii) 36 E_(1b)E₅E_(iii) 37 E_(1a)E_(iii)E₄ 38 E_(1b)E_(iii)E₄ 39 E_(1a)E₅E_(iii)E₄ 40 E_(1b)E₅E_(iii)E₄ 41 E_(1a)E_(iv) 42 E_(1b)E_(iv) 43 E_(1a)E₅E_(iv) 44 E_(1b)E₅E_(iv) 45 E_(1a)E_(iv)E₄ 46 E_(1b)E_(iv)E₄ 47 E_(1a)E₅E_(iv)E₄ 48 E_(1b)E₅E_(iv)E₄ 49 E_(1a) E₄* 50 E_(1b) E₄* 51 E_(1a)E₅ E₄* 52 E_(1b)E₅ E₄* 53 E_(1a)E_(i) E₄* 54 E_(1b)E_(i) E₄* 55 E_(1a)E_(ii) E₄* 56 E_(1b)E_(ii) E₄* 57 E_(1a)E_(ii)E_(iib) E₄* 58 E_(1b)E_(ii)E_(iib) E₄* 59 E_(1a)E₅E_(i) E₄* 60 E_(1b)E₅E_(i) E₄* 61 E_(1a)E₅E_(ii) E₄* 62 E_(1b)E₅E_(ii) E₄* 63 E_(1a)E₅E_(ii)E_(iib) E₄* 64 E_(1b)E₅E_(ii)E_(iib) E₄* 65 E_(1a)E₄ E₄* 66 E_(1b)E₄ E₄* 67 E_(1a)E₅E₄ E₄* 68 E_(1b)E₅E₄ E₄* 69 E_(1a)E_(i)E₄ E₄* 70 E_(1b)E_(i)E₄ E₄* 71 E_(1a)E_(ii)E₄ E₄* 72 E_(1b)E_(ii)E₄ E₄* 73 E_(1a)E_(ii)E_(iib)E₄ E₄* 74 E_(1b)E_(ii)E_(iib)E₄ E₄* 75 E_(1a)E₅E_(i)E₄ E₄* 76 E_(1b)E₅E_(i)E₄ E₄* 77 E_(1a)E₅E_(ii)E₄ E₄* 78 E_(1b)E₅E_(ii)E₄ E₄* 79 E_(1a)E₅E_(ii)E_(iib)E₄ E₄* 80 E_(1b)E₅E_(ii)E_(iib)E₄ E₄* 81 E_(1a)E_(iii) E₄* 82 E_(1b)E_(iii) E₄* 83 E_(1a)E₅E_(iii) E₄* 84 E_(1b)E₅E_(iii) E₄* 85 E_(1a)E_(iii)E₄ E₄* 86 E_(1b)E_(iii)E₄ E₄* 87 E_(1a)E₅E_(iii)E₄ E₄* 88 E_(1b)E₅E_(iii)E₄ E₄* 89 E_(1a)E_(iv) E₄* 90 E_(1b)E_(iv) E₄* 91 E_(1a)E₅E_(iv) E₄* 92 E_(1b)E₅E_(iv) E₄* 93 E_(1a)E_(iv)E₄ E₄* 94 E_(1b)E_(iv)E₄ E₄* 95 E_(1a)E₅E_(iv)E₄ E₄* 96 E_(1b)E₅E_(iv)E₄ E₄* 97 E_(1a) AlkL 98 E_(1b) AlkL 99 E_(1a)E₅ AlkL 100 E_(1b)E₅ AlkL 101 E_(1a)E_(i) AlkL 102 E_(1b)E_(i) AlkL 103 E_(1a)E_(ii) AlkL 104 E_(1b)E_(ii) AlkL 105 E_(1a)E_(ii)E_(iib) AlkL 106 E_(1b)E_(ii)E_(iib) AlkL 107 E_(1a)E₅E_(i) AlkL 108 E_(1b)E₅E_(i) AlkL 109 E_(1a)E₅E_(ii) AlkL 110 E_(1b)E₅E_(ii) AlkL 111 E_(1a)E₅E_(ii)E_(iib) AlkL 112 E_(1b)E₅E_(ii)E_(iib) AlkL 113 E_(1a)E₄ AlkL 114 E_(1b)E₄ AlkL 115 E_(1a)E₅E₄ AlkL 116 E_(1b)E₅E₄ AlkL 117 E_(1a)E_(i)E₄ AlkL 118 E_(1b)E_(i)E₄ AlkL 119 E_(1a)E_(ii)E₄ AlkL 120 E_(1b)E_(ii)E₄ AlkL 121 E_(1a)E_(ii)E_(iib)E₄ AlkL 122 E_(1b)E_(ii)E_(iib)E₄ AlkL 123 E_(1a)E₅E_(i)E₄ AlkL 124 E_(1b)E₅E_(i)E₄ AlkL 125 E_(1a)E₅E_(ii)E₄ AlkL 126 E_(1b)E₅E_(ii)E₄ AlkL 127 E_(1a)E₅E_(ii)E_(iib)E₄ AlkL 128 E_(1b)E₅E_(ii)E_(iib)E₄ AlkL 129 E_(1a)E_(iii) AlkL 130 E_(1b)E_(iii) AlkL 131 E_(1a)E₅E_(iii) AlkL 132 E_(1b)E₅E_(iii) AlkL 133 E_(1a)E_(iii)E₄ AlkL 134 E_(1b)E_(iii)E₄ AlkL 135 E_(1a)E₅E_(iii)E₄ AlkL 136 E_(1b)E₅E_(iii)E₄ AlkL 137 E_(1a)E_(iv) AlkL 138 E_(1b)E_(iv) AlkL 139 E_(1a)E₅E_(iv) AlkL 140 E_(1b)E₅E_(iv) AlkL 141 E_(1a)E_(iv)E₄ AlkL 142 E_(1b)E_(iv)E₄ AlkL 143 E_(1a)E₅E_(iv)E₄ AlkL 144 E_(1b)E₅E_(iv)E₄ AlkL 145 E_(1a) AlkL E₄* 146 E_(1b) AlkL E₄* 147 E_(1a)E₅ AlkL E₄* 148 E_(1b)E₅ AlkL E₄* 149 E_(1a)E_(i) AlkL E₄* 150 E_(1b)E_(i) AlkL E₄* 151 E_(1a)E_(ii) AlkL E₄* 152 E_(1b)E_(ii) AlkL E₄* 153 E_(1a)E_(ii)E_(iib) AlkL E₄* 154 E_(1b)E_(ii)E_(iib) AlkL E₄* 155 E_(1a)E₅E_(i) AlkL E₄* 156 E_(1b)E₅E_(i) AlkL E₄* 157 E_(1a)E₅E_(ii) AlkL E₄* 158 E_(1b)E₅E_(ii) AlkL E₄* 159 E_(1a)E₅E_(ii)E_(iib) AlkL E₄* 160 E_(1b)E₅E_(ii)E_(iib) AlkL E₄* 161 E_(1a)E₄ AlkL E₄* 162 E_(1b)E₄ AlkL E₄* 163 E_(1a)E₅E₄ AlkL E₄* 164 E_(1b)E₅E₄ AlkL E₄* 165 E_(1a)E_(i)E₄ AlkL E₄* 166 E_(1b)E_(i)E₄ AlkL E₄* 167 E_(1a)E_(ii)E₄ AlkL E₄* 168 E_(1b)E_(ii)E₄ AlkL E₄* 169 E_(1a)E_(ii)E_(iib)E₄ AlkL E₄* 170 E_(1b)E_(ii)E_(iib)E₄ AlkL E₄* 171 E_(1a)E₅E_(i)E₄ AlkL E₄* 172 E_(1b)E₅E_(i)E₄ AlkL E₄* 173 E_(1a)E₅E_(ii)E₄ AlkL E₄* 174 E_(1b)E₅E_(ii)E₄ AlkL E₄* 175 E_(1a)E₅E_(ii)E_(iib)E₄ AlkL E₄* 176 E_(1b)E₅E_(ii)E_(iib)E₄ AlkL E₄* 177 E_(1a)E_(iii) AlkL E₄* 178 E_(1b)E_(iii) AlkL E₄* 179 E_(1a)E₅E_(iii) AlkL E₄* 180 E_(1b)E₅E_(iii) AlkL E₄* 181 E_(1a)E_(iii)E₄ AlkL E₄* 182 E_(1b)E_(iii)E₄ AlkL E₄* 183 E_(1a)E₅E_(iii)E₄ AlkL E₄* 184 E_(1b)E₅E_(iii)E₄ AlkL E₄* 185 E_(1a)E_(iv) AlkL E₄* 186 E_(1b)E_(iv) AlkL E₄* 187 E_(1a)E₅E_(iv) AlkL E₄* 188 E_(1b)E₅E_(iv) AlkL E₄* 189 E_(1a)E_(iv)E₄ AlkL E₄* 190 E_(1b)E_(iv)E₄ AlkL E₄* 191 E_(1a)E₅E_(iv)E₄ AlkL E₄* 192 E_(1b)E₅E_(iv)E₄ AlkL E₄* 193 E_(1a) E_(a) 194 E_(1b) E_(a) 195 E_(1a)E₅ E_(a) 196 E_(1b)E₅ E_(a) 197 E_(1a)E_(i) E_(a) 198 E_(1b)E_(i) E_(a) 199 E_(1a)E_(ii) E_(a) 200 E_(1b)E_(ii) E_(a) 201 E_(1a)E_(ii)E_(iib) E_(a) 202 E_(1b)E_(ii)E_(iib) E_(a) 203 E_(1a)E₅E_(i) E_(a) 204 E_(1b)E₅E_(i) E_(a) 205 E_(1a)E₅E_(ii) E_(a) 206 E_(1b)E₅E_(ii) E_(a) 207 E_(1a)E₅E_(ii)E_(iib) E_(a) 208 E_(1b)E₅E_(ii)E_(iib) E_(a) 209 E_(1a)E₄ E_(a) 210 E_(1b)E₄ E_(a) 211 E_(1a)E₅E₄ E_(a) 212 E_(1b)E₅E₄ E_(a) 213 E_(1a)E_(i)E₄ E_(a) 214 E_(1b)E_(i)E₄ E_(a) 215 E_(1a)E_(ii)E₄ E_(a) 216 E_(1b)E_(ii)E₄ E_(a) 217 E_(1a)E_(ii)E_(iib)E₄ E_(a) 218 E_(1b)E_(ii)E_(iib)E₄ E_(a) 219 E_(1a)E₅E_(i)E₄ E_(a) 220 E_(1b)E₅E_(i)E₄ E_(a) 221 E_(1a)E₅E_(ii)E₄ E_(a) 222 E_(1b)E₅E_(ii)E₄ E_(a) 223 E_(1a)E₅E_(ii)E_(iib)E₄ E_(a) 224 E_(1b)E₅E_(ii)E_(iib)E₄ E_(a) 225 E_(1a)E_(iii) E_(a) 226 E_(1b)E_(iii) E_(a) 227 E_(1a)E₅E_(iii) E_(a) 228 E_(1b)E₅E_(iii) E_(a) 229 E_(1a)E_(iii)E₄ E_(a) 230 E_(1b)E_(iii)E₄ E_(a) 231 E_(1a)E₅E_(iii)E₄ E_(a) 232 E_(1b)E₅E_(iii)E₄ E_(a) 233 E_(1a)E_(iv) E_(a) 234 E_(1b)E_(iv) E_(a) 235 E_(1a)E₅E_(iv) E_(a) 236 E_(1b)E₅E_(iv) E_(a) 237 E_(1a)E_(iv)E₄ E_(a) 238 E_(1b)E_(iv)E₄ E_(a) 239 E_(1a)E₅E_(iv)E₄ E_(a) 240 E_(1b)E₅E_(iv)E₄ E_(a) 241 E_(1a) E₄* E_(a) 242 E_(1b) E₄* E_(a) 243 E_(1a)E₅ E₄* E_(a) 244 E_(1b)E₅ E₄* E_(a) 245 E_(1a)E_(i) E₄* E_(a) 246 E_(1b)E_(i) E₄* E_(a) 247 E_(1a)E_(ii) E₄* E_(a) 248 E_(1b)E_(ii) E₄* E_(a) 249 E_(1a)E_(ii)E_(iib) E₄* E_(a) 250 E_(1b)E_(ii)E_(iib) E₄* E_(a) 251 E_(1a)E₅E_(i) E₄* E_(a) 252 E_(1b)E₅E_(i) E₄* E_(a) 253 E_(1a)E₅E_(ii) E₄* E_(a) 254 E_(1b)E₅E_(ii) E₄* E_(a) 255 E_(1a)E₅E_(ii)E_(iib) E₄* E_(a) 256 E_(1b)E₅E_(ii)E_(iib) E₄* E_(a) 257 E_(1a)E₄ E₄* E_(a) 258 E_(1b)E₄ E₄* E_(a) 259 E_(1a)E₅E₄ E₄* E_(a) 260 E_(1b)E₅E₄ E₄* E_(a) 261 E_(1a)E_(i)E₄ E₄* E_(a) 262 E_(1b)E_(i)E₄ E₄* E_(a) 263 E_(1a)E_(ii)E₄ E₄* E_(a) 264 E_(1b)E_(ii)E₄ E₄* E_(a) 265 E_(1a)E_(ii)E_(iib)E₄ E₄* E_(a) 266 E_(1b)E_(ii)E_(iib)E₄ E₄* E_(a) 267 E_(1a)E₅E_(i)E₄ E₄* E_(a) 268 E_(1b)E₅E_(i)E₄ E₄* E_(a) 269 E_(1a)E₅E_(ii)E₄ E₄* E_(a) 270 E_(1b)E₅E_(ii)E₄ E₄* E_(a) 271 E_(1a)E₅E_(ii)E_(iib)E₄ E₄* E_(a) 272 E_(1b)E₅E_(ii)E_(iib)E₄ E₄* E_(a) 273 E_(1a)E_(iii) E₄* E_(a) 274 E_(1b)E_(iii) E₄* E_(a) 275 E_(1a)E₅E_(iii) E₄* E_(a) 276 E_(1b)E₅E_(iii) E₄* E_(a) 277 E_(1a)E_(iii)E₄ E₄* E_(a) 278 E_(1b)E_(iii)E₄ E₄* E_(a) 279 E_(1a)E₅E_(iii)E₄ E₄* E_(a) 280 E_(1b)E₅E_(iii)E₄ E₄* E_(a) 281 E_(1a)E_(iv) E₄* E_(a) 282 E_(1b)E_(iv) E₄* E_(a) 283 E_(1a)E₅E_(iv) E₄* E_(a) 284 E_(1b)E₅E_(iv) E₄* E_(a) 285 E_(1a)E_(iv)E₄ E₄* E_(a) 286 E_(1b)E_(iv)E₄ E₄* E_(a) 287 E_(1a)E₅E_(iv)E₄ E₄* E_(a) 288 E_(1b)E₅E_(iv)E₄ E₄* E_(a) 289 E_(1a) AlkL E_(a) 290 E_(1b) AlkL E_(a) 291 E_(1a)E₅ AlkL E_(a) 292 E_(1b)E₅ AlkL E_(a) 293 E_(1a)E_(i) AlkL E_(a) 294 E_(1b)E_(i) AlkL E_(a) 295 E_(1a)E_(ii) AlkL E_(a) 296 E_(1b)E_(ii) AlkL E_(a) 297 E_(1a)E_(ii)E_(iib) AlkL E_(a) 298 E_(1b)E_(ii)E_(iib) AlkL E_(a) 299 E_(1a)E₅E_(i) AlkL E_(a) 300 E_(1b)E₅E_(i) AlkL E_(a) 301 E_(1a)E₅E_(ii) AlkL E_(a) 302 E_(1b)E₅E_(ii) AlkL E_(a) 303 E_(1a)E₅E_(ii)E_(iib) AlkL E_(a) 304 E_(1b)E₅E_(ii)E_(iib) AlkL E_(a) 305 E_(1a)E₄ AlkL E_(a) 306 E_(1b)E₄ AlkL E_(a) 307 E_(1a)E₅E₄ AlkL E_(a) 308 E_(1b)E₅E₄ AlkL E_(a) 309 E_(1a)E_(i)E₄ AlkL E_(a) 310 E_(1b)E_(i)E₄ AlkL E_(a) 311 E_(1a)E_(ii)E₄ AlkL E_(a) 312 E_(1b)E_(ii)E₄ AlkL E_(a) 313 E_(1a)E_(ii)E_(iib)E₄ AlkL E_(a) 314 E_(1b)E_(ii)E_(iib)E₄ AlkL E_(a) 315 E_(1a)E₅E_(i)E₄ AlkL E_(a) 316 E_(1b)E₅E_(i)E₄ AlkL E_(a) 317 E_(1a)E₅E_(ii)E₄ AlkL E_(a) 318 E_(1b)E₅E_(ii)E₄ AlkL E_(a) 319 E_(1a)E₅E_(ii)E_(iib)E₄ AlkL E_(a) 320 E_(1b)E₅E_(ii)E_(iib)E₄ AlkL E_(a) 321 E_(1a)E_(iii) AlkL E_(a) 322 E_(1b)E_(iii) AlkL E_(a) 323 E_(1a)E₅E_(iii) AlkL E_(a) 324 E_(1b)E₅E_(iii) AlkL E_(a) 325 E_(1a)E_(iii)E₄ AlkL E_(a) 326 E_(1b)E_(iii)E₄ AlkL E_(a) 327 E_(1a)E₅E_(iii)E₄ AlkL E_(a) 328 E_(1b)E₅E_(iii)E₄ AlkL E_(a) 329 E_(1a)E_(iv) AlkL E_(a) 330 E_(1b)E_(iv) AlkL E_(a) 331 E_(1a)E₅E_(iv) AlkL E_(a) 332 E_(1b)E₅E_(iv) AlkL E_(a) 333 E_(1a)E_(iv)E₄ AlkL E_(a) 334 E_(1b)E_(iv)E₄ AlkL E_(a) 335 E_(1a)E₅E_(iv)E₄ AlkL E_(a) 336 E_(1b)E₅E_(iv)E₄ AlkL E_(a) 337 E_(1a) AlkL E₄* E_(a) 338 E_(1b) AlkL E₄* E_(a) 339 E_(1a)E₅ AlkL E₄* E_(a) 340 E_(1b)E₅ AlkL E₄* E_(a) 341 E_(1a)E_(i) AlkL E₄* E_(a) 342 E_(1b)E_(i) AlkL E₄* E_(a) 343 E_(1a)E_(ii) AlkL E₄* E_(a) 344 E_(1b)E_(ii) AlkL E₄* E_(a) 345 E_(1a)E_(ii)E_(iib) AlkL E₄* E_(a) 346 E_(1b)E_(ii)E_(iib) AlkL E₄* E_(a) 347 E_(1a)E₅E_(i) AlkL E₄* E_(a) 348 E_(1b)E₅E_(i) AlkL E₄* E_(a) 349 E_(1a)E₅E_(ii) AlkL E₄* E_(a) 350 E_(1b)E₅E_(ii) AlkL E₄* E_(a) 351 E_(1a)E₅E_(ii)E_(iib) AlkL E₄* E_(a) 352 E_(1b)E₅E_(ii)E_(iib) AlkL E₄* E_(a) 353 E_(1a)E₄ AlkL E₄* E_(a) 354 E_(1b)E₄ AlkL E₄* E_(a) 355 E_(1a)E₅E₄ AlkL E₄* E_(a) 356 E_(1b)E₅E₄ AlkL E₄* E_(a) 357 E_(1a)E_(i)E₄ AlkL E₄* E_(a) 358 E_(1b)E_(i)E₄ AlkL E₄* E_(a) 359 E_(1a)E_(ii)E₄ AlkL E₄* E_(a) 360 E_(1b)E_(ii)E₄ AlkL E₄* E_(a) 361 E_(1a)E_(ii)E_(iib)E₄ AlkL E₄* E_(a) 362 E_(1b)E_(ii)E_(iib)E₄ AlkL E₄* E_(a) 363 E_(1a)E₅E_(i)E₄ AlkL E₄* E_(a) 364 E_(1b)E₅E_(i)E₄ AlkL E₄* E_(a) 365 E_(1a)E₅E_(ii)E₄ AlkL E₄* E_(a) 366 E_(1b)E₅E_(ii)E₄ AlkL E₄* E_(a) 367 E_(1a)E₅E_(ii)E_(iib)E₄ AlkL E₄* E_(a) 368 E_(1b)E₅E_(ii)E_(iib)E₄ AlkL E₄* E_(a) 369 E_(1a)E_(iii) AlkL E₄* E_(a) 370 E_(1b)E_(iii) AlkL E₄* E_(a) 371 E_(1a)E₅E_(iii) AlkL E₄* E_(a) 372 E_(1b)E₅E_(iii) AlkL E₄* E_(a) 373 E_(1a)E_(iii)E₄ AlkL E₄* E_(a) 374 E_(1b)E_(iii)E₄ AlkL E₄* E_(a) 375 E_(1a)E₅E_(iii)E₄ AlkL E₄* E_(a) 376 E_(1b)E₅E_(iii)E₄ AlkL E₄* E_(a) 377 E_(1a)E_(iv) AlkL E₄* E_(a) 378 E_(1b)E_(iv) AlkL E₄* E_(a) 379 E_(1a)E₅E_(iv) AlkL E₄* E_(a) 380 E_(1b)E₅E_(iv) AlkL E₄* E_(a) 381 E_(1a)E_(iv)E₄ AlkL E₄* E_(a) 382 E_(1b)E_(iv)E₄ AlkL E₄* E_(a) 383 E_(1a)E₅E_(iv)E₄ AlkL E₄* E_(a) 384 E_(1b)E₅E_(iv)E₄ AlkL E₄* E_(a) 385 E_(1a) E_(b) 386 E_(1b) E_(b) 387 E_(1a)E₅ E_(b) 388 E_(1b)E₅ E_(b) 389 E_(1a)E_(i) E_(b) 390 E_(1b)E_(i) E_(b) 391 E_(1a)E_(ii) E_(b) 392 E_(1b)E_(ii) E_(b) 393 E_(1a)E_(ii)E_(iib) E_(b) 394 E_(1b)E_(ii)E_(iib) E_(b) 395 E_(1a)E₅E_(i) E_(b) 396 E_(1b)E₅E_(i) E_(b) 397 E_(1a)E₅E_(ii) E_(b) 398 E_(1b)E₅E_(ii) E_(b) 399 E_(1a)E₅E_(ii)E_(iib) E_(b) 400 E_(1b)E₅E_(ii)E_(iib) E_(b) 401 E_(1a)E₄ E_(b) 402 E_(1b)E₄ E_(b) 403 E_(1a)E₅E₄ E_(b) 404 E_(1b)E₅E₄ E_(b) 405 E_(1a)E_(i)E₄ E_(b) 406 E_(1b)E_(i)E₄ E_(b) 407 E_(1a)E_(ii)E₄ E_(b) 408 E_(1b)E_(ii)E₄ E_(b) 409 E_(1a)E_(ii)E_(iib)E₄ E_(b) 410 E_(1b)E_(ii)E_(iib)E₄ E_(b) 411 E_(1a)E₅E_(i)E₄ E_(b) 412 E_(1b)E₅E_(i)E₄ E_(b) 413 E_(1a)E₅E_(ii)E₄ E_(b) 414 E_(1b)E₅E_(ii)E₄ E_(b) 415 E_(1a)E₅E_(ii)E_(iib)E₄ E_(b) 416 E_(1b)E₅E_(ii)E_(iib)E₄ E_(b) 417 E_(1a)E_(iii) E_(b) 418 E_(1b)E_(iii) E_(b) 419 E_(1a)E₅E_(iii) E_(b) 420 E_(1b)E₅E_(iii) E_(b) 421 E_(1a)E_(iii)E₄ E_(b) 422 E_(1b)E_(iii)E₄ E_(b) 423 E_(1a)E₅E_(iii)E₄ E_(b) 424 E_(1b)E₅E_(iii)E₄ E_(b) 425 E_(1a)E_(iv) E_(b) 426 E_(1b)E_(iv) E_(b) 427 E_(1a)E₅E_(iv) E_(b) 428 E_(1b)E₅E_(iv) E_(b) 429 E_(1a)E_(iv)E₄ E_(b) 430 E_(1b)E_(iv)E₄ E_(b) 431 E_(1a)E₅E_(iv)E₄ E_(b) 432 E_(1b)E₅E_(iv)E₄ E_(b) 433 E_(1a) E₄* E_(b) 434 E_(1b) E₄* E_(b) 435 E_(1a)E₅ E₄* E_(b) 436 E_(1b)E₅ E₄* E_(b) 437 E_(1a)E_(i) E₄* E_(b) 438 E_(1b)E_(i) E₄* E_(b) 439 E_(1a)E_(ii) E₄* E_(b) 440 E_(1b)E_(ii) E₄* E_(b) 441 E_(1a)E_(ii)E_(iib) E₄* E_(b) 442 E_(1b)E_(ii)E_(iib) E₄* E_(b) 443 E_(1a)E₅E_(i) E₄* E_(b) 444 E_(1b)E₅E_(i) E₄* E_(b) 445 E_(1a)E₅E_(ii) E₄* E_(b) 446 E_(1b)E₅E_(ii) E₄* E_(b) 447 E_(1a)E₅E_(ii)E_(iib) E₄* E_(b) 448 E_(1b)E₅E_(ii)E_(iib) E₄* E_(b) 449 E_(1a)E₄ E₄* E_(b) 450 E_(1b)E₄ E₄* E_(b) 451 E_(1a)E₅E₄ E₄* E_(b) 452 E_(1b)E₅E₄ E₄* E_(b) 453 E_(1a)E_(i)E₄ E₄* E_(b) 454 E_(1b)E_(i)E₄ E₄* E_(b) 455 E_(1a)E_(ii)E₄ E₄* E_(b) 456 E_(1b)E_(ii)E₄ E₄* E_(b) 457 E_(1a)E_(ii)E_(iib)E₄ E₄* E_(b) 458 E_(1b)E_(ii)E_(iib)E₄ E₄* E_(b) 459 E_(1a)E₅E_(i)E₄ E₄* E_(b) 460 E_(1b)E₅E_(i)E₄ E₄* E_(b) 461 E_(1a)E₅E_(ii)E₄ E₄* E_(b) 462 E_(1b)E₅E_(ii)E₄ E₄* E_(b) 463 E_(1a)E₅E_(ii)E_(iib)E₄ E₄* E_(b) 464 E_(1b)E₅E_(ii)E_(iib)E₄ E₄* E_(b) 465 E_(1a)E_(iii) E₄* E_(b) 466 E_(1b)E_(iii) E₄* E_(b) 467 E_(1a)E₅E_(iii) E₄* E_(b) 468 E_(1b)E₅E_(iii) E₄* E_(b) 469 E_(1a)E_(iii)E₄ E₄* E_(b) 470 E_(1b)E_(iii)E₄ E₄* E_(b) 471 E_(1a)E₅E_(iii)E₄ E₄* E_(b) 472 E_(1b)E₅E_(iii)E₄ E₄* E_(b) 473 E_(1a)E_(iv) E₄* E_(b) 474 E_(1b)E_(iv) E₄* E_(b) 475 E_(1a)E₅E_(iv) E₄* E_(b) 476 E_(1b)E₅E_(iv) E₄* E_(b) 477 E_(1a)E_(iv)E₄ E₄* E_(b) 478 E_(1b)E_(iv)E₄ E₄* E_(b) 479 E_(1a)E₅E_(iv)E₄ E₄* E_(b) 480 E_(1b)E₅E_(iv)E₄ E₄* E_(b) 481 E_(1a) AlkL E_(b) 482 E_(1b) AlkL E_(b) 483 E_(1a)E₅ AlkL E_(b) 484 E_(1b)E₅ AlkL E_(b) 485 E_(1a)E_(i) AlkL E_(b) 486 E_(1b)E_(i) AlkL E_(b) 487 E_(1a)E_(ii) AlkL E_(b) 488 E_(1b)E_(ii) AlkL E_(b) 489 E_(1a)E_(ii)E_(iib) AlkL E_(b) 490 E_(1b)E_(ii)E_(iib) AlkL E_(b) 491 E_(1a)E₅E_(i) AlkL E_(b) 492 E_(1b)E₅E_(i) AlkL E_(b) 493 E_(1a)E₅E_(ii) AlkL E_(b) 494 E_(1b)E₅E_(ii) AlkL E_(b) 495 E_(1a)E₅E_(ii)E_(iib) AlkL E_(b) 496 E_(1b)E₅E_(ii)E_(iib) AlkL E_(b) 497 E_(1a)E₄ AlkL E_(b) 498 E_(1b)E₄ AlkL E_(b) 499 E_(1a)E₅E₄ AlkL E_(b) 500 E_(1b)E₅E₄ AlkL E_(b) 501 E_(1a)E_(i)E₄ AlkL E_(b) 502 E_(1b)E_(i)E₄ AlkL E_(b) 503 E_(1a)E_(ii)E₄ AlkL E_(b) 504 E_(1b)E_(ii)E₄ AlkL E_(b) 505 E_(1a)E_(ii)E_(iib)E₄ AlkL E_(b) 506 E_(1b)E_(ii)E_(iib)E₄ AlkL E_(b) 507 E_(1a)E₅E_(i)E₄ AlkL E_(b) 508 E_(1b)E₅E_(i)E₄ AlkL E_(b) 509 E_(1a)E₅E_(ii)E₄ AlkL E_(b) 510 E_(1b)E₅E_(ii)E₄ AlkL E_(b) 511 E_(1a)E₅E_(ii)E_(iib)E₄ AlkL E_(b) 512 E_(1b)E₅E_(ii)E_(iib)E₄ AlkL E_(b) 513 E_(1a)E_(iii) AlkL E_(b) 514 E_(1b)E_(iii) AlkL E_(b) 515 E_(1a)E₅E_(iii) AlkL E_(b) 516 E_(1b)E₅E_(iii) AlkL E_(b) 517 E_(1a)E_(iii)E₄ AlkL E_(b) 518 E_(1b)E_(iii)E₄ AlkL E_(b) 519 E_(1a)E₅E_(iii)E₄ AlkL E_(b) 520 E_(1b)E₅E_(iii)E₄ AlkL E_(b) 521 E_(1a)E_(iv) AlkL E_(b) 522 E_(1b)E_(iv) AlkL E_(b) 523 E_(1a)E₅E_(iv) AlkL E_(b) 524 E_(1b)E₅E_(iv) AlkL E_(b) 525 E_(1a)E_(iv)E₄ AlkL E_(b) 526 E_(1b)E_(iv)E₄ AlkL E_(b) 527 E_(1a)E₅E_(iv)E₄ AlkL E_(b) 528 E_(1b)E₅E_(iv)E₄ AlkL E_(b) 529 E_(1a) AlkL E₄* E_(b) 530 E_(1b) AlkL E₄* E_(b) 531 E_(1a)E₅ AlkL E₄* E_(b) 532 E_(1b)E₅ AlkL E₄* E_(b) 533 E_(1a)E_(i) AlkL E₄* E_(b) 534 E_(1b)E_(i) AlkL E₄* E_(b) 535 E_(1a)E_(ii) AlkL E₄* E_(b) 536 E_(1b)E_(ii) AlkL E₄* E_(b) 537 E_(1a)E_(ii)E_(iib) AlkL E₄* E_(b) 538 E_(1b)E_(ii)E_(iib) AlkL E₄* E_(b) 539 E_(1a)E₅E_(i) AlkL E₄* E_(b) 540 E_(1b)E₅E_(i) AlkL E₄* E_(b) 541 E_(1a)E₅E_(ii) AlkL E₄* E_(b) 542 E_(1b)E₅E_(ii) AlkL E₄* E_(b) 543 E_(1a)E₅E_(ii)E_(iib) AlkL E₄* E_(b) 544 E_(1b)E₅E_(ii)E_(iib) AlkL E₄* E_(b) 545 E_(1a)E₄ AlkL E₄* E_(b) 546 E_(1b)E₄ AlkL E₄* E_(b) 547 E_(1a)E₅E₄ AlkL E₄* E_(b) 548 E_(1b)E₅E₄ AlkL E₄* E_(b) 549 E_(1a)E_(i)E₄ AlkL E₄* E_(b) 550 E_(1b)E_(i)E₄ AlkL E₄* E_(b) 551 E_(1a)E_(ii)E₄ AlkL E₄* E_(b) 552 E_(1b)E_(ii)E₄ AlkL E₄* E_(b) 553 E_(1a)E_(ii)E_(iib)E₄ AlkL E₄* E_(b) 554 E_(1b)E_(ii)E_(iib)E₄ AlkL E₄* E_(b) 555 E_(1a)E₅E_(i)E₄ AlkL E₄* E_(b) 556 E_(1b)E₅E_(i)E₄ AlkL E₄* E_(b) 557 E_(1a)E₅E_(ii)E₄ AlkL E₄* E_(b) 558 E_(1b)E₅E_(ii)E₄ AlkL E₄* E_(b) 559 E_(1a)E₅E_(ii)E_(iib)E₄ AlkL E₄* E_(b) 560 E_(1b)E₅E_(ii)E_(iib)E₄ AlkL E₄* E_(b) 561 E_(1a)E_(iii) AlkL E₄* E_(b) 562 E_(1b)E_(iii) AlkL E₄* E_(b) 563 E_(1a)E₅E_(iii) AlkL E₄* E_(b) 564 E_(1b)E₅E_(iii) AlkL E₄* E_(b) 565 E_(1a)E_(iii)E₄ AlkL E₄* E_(b) 566 E_(1b)E_(iii)E₄ AlkL E₄* E_(b) 567 E_(1a)E₅E_(iii)E₄ AlkL E₄* E_(b) 568 E_(1b)E₅E_(iii)E₄ AlkL E₄* E_(b) 569 E_(1a)E_(iv) AlkL E₄* E_(b) 570 E_(1b)E_(iv) AlkL E₄* E_(b) 571 E_(1a)E₅E_(iv) AlkL E₄* E_(b) 572 E_(1b)E₅E_(iv) AlkL E₄* E_(b) 573 E_(1a)E_(iv)E₄ AlkL E₄* E_(b) 574 E_(1b)E_(iv)E₄ AlkL E₄* E_(b) 575 E_(1a)E₅E_(iv)E₄ AlkL E₄* E_(b) 576 E_(1b)E₅E_(iv)E₄ AlkL E₄* E_(b) 577 E_(1a) E_(d) 578 E_(1b) E_(d) 579 E_(1a)E₅ E_(d) 580 E_(1b)E₅ E_(d) 581 E_(1a)E_(i) E_(d) 582 E_(1b)E_(i) E_(d) 583 E_(1a)E_(ii) E_(d) 584 E_(1b)E_(ii) E_(d) 585 E_(1a)E_(ii)E_(iib) E_(d) 586 E_(1b)E_(ii)E_(iib) E_(d) 587 E_(1a)E₅E_(i) E_(d) 588 E_(1b)E₅E_(i) E_(d) 589 E_(1a)E₅E_(ii) E_(d) 590 E_(1b)E₅E_(ii) E_(d) 591 E_(1a)E₅E_(ii)E_(iib) E_(d) 592 E_(1b)E₅E_(ii)E_(iib) E_(d) 593 E_(1a)E₄ E_(d) 594 E_(1b)E₄ E_(d) 595 E_(1a)E₅E₄ E_(d) 596 E_(1b)E₅E₄ E_(d) 597 E_(1a)E_(i)E₄ E_(d) 598 E_(1b)E_(i)E₄ E_(d) 599 E_(1a)E_(ii)E₄ E_(d) 600 E_(1b)E_(ii)E₄ E_(d) 601 E_(1a)E_(ii)E_(iib)E₄ E_(d) 602 E_(1b)E_(ii)E_(iib)E₄ E_(d) 603 E_(1a)E₅E_(i)E₄ E_(d) 604 E_(1b)E₅E_(i)E₄ E_(d) 605 E_(1a)E₅E_(ii)E₄ E_(d) 606 E_(1b)E₅E_(ii)E₄ E_(d) 607 E_(1a)E₅E_(ii)E_(iib)E₄ E_(d) 608 E_(1b)E₅E_(ii)E_(iib)E₄ E_(d) 609 E_(1a)E_(iii) E_(d) 610 E_(1b)E_(iii) E_(d) 611 E_(1a)E₅E_(iii) E_(d) 612 E_(1b)E₅E_(iii) E_(d) 613 E_(1a)E_(iii)E₄ E_(d) 614 E_(1b)E_(iii)E₄ E_(d) 615 E_(1a)E₅E_(iii)E₄ E_(d) 616 E_(1b)E₅E_(iii)E₄ E_(d) 617 E_(1a)E_(iv) E_(d) 618 E_(1b)E_(iv) E_(d) 619 E_(1a)E₅E_(iv) E_(d) 620 E_(1b)E₅E_(iv) E_(d) 621 E_(1a)E_(iv)E₄ E_(d) 622 E_(1b)E_(iv)E₄ E_(d) 623 E_(1a)E₅E_(iv)E₄ E_(d) 624 E_(1b)E₅E_(iv)E₄ E_(d) 625 E_(1a) E₄* E_(d) 626 E_(1b) E₄* E_(d) 627 E_(1a)E₅ E₄* E_(d) 628 E_(1b)E₅ E₄* E_(d) 629 E_(1a)E_(i) E₄* E_(d) 630 E_(1b)E_(i) E₄* E_(d) 631 E_(1a)E_(ii) E₄* E_(d) 632 E_(1b)E_(ii) E₄* E_(d) 633 E_(1a)E_(ii)E_(iib) E₄* E_(d) 634 E_(1b)E_(ii)E_(iib) E₄* E_(d) 635 E_(1a)E₅E_(i) E₄* E_(d) 636 E_(1b)E₅E_(i) E₄* E_(d) 637 E_(1a)E₅E_(ii) E₄* E_(d) 638 E_(1b)E₅E_(ii) E₄* E_(d) 639 E_(1a)E₅E_(ii)E_(iib) E₄* E_(d) 640 E_(1b)E₅E_(ii)E_(iib) E₄* E_(d) 641 E_(1a)E₄ E₄* E_(d) 642 E_(1b)E₄ E₄* E_(d) 643 E_(1a)E₅E₄ E₄* E_(d) 644 E_(1b)E₅E₄ E₄* E_(d) 645 E_(1a)E_(i)E₄ E₄* E_(d) 646 E_(1b)E_(i)E₄ E₄* E_(d) 647 E_(1a)E_(ii)E₄ E₄* E_(d) 648 E_(1b)E_(ii)E₄ E₄* E_(d) 649 E_(1a)E_(ii)E_(iib)E₄ E₄* E_(d) 650 E_(1b)E_(ii)E_(iib)E₄ E₄* E_(d) 651 E_(1a)E₅E_(i)E₄ E₄* E_(d) 652 E_(1b)E₅E_(i)E₄ E₄* E_(d) 653 E_(1a)E₅E_(ii)E₄ E₄* E_(d) 654 E_(1b)E₅E_(ii)E₄ E₄* E_(d) 655 E_(1a)E₅E_(ii)E_(iib)E₄ E₄* E_(d) 656 E_(1b)E₅E_(ii)E_(iib)E₄ E₄* E_(d) 657 E_(1a)E_(iii) E₄* E_(d) 658 E_(1b)E_(iii) E₄* E_(d) 659 E_(1a)E₅E_(iii) E₄* E_(d) 660 E_(1b)E₅E_(iii) E₄* E_(d) 661 E_(1a)E_(iii)E₄ E₄* E_(d) 662 E_(1b)E_(iii)E₄ E₄* E_(d) 663 E_(1a)E₅E_(iii)E₄ E₄* E_(d) 664 E_(1b)E₅E_(iii)E₄ E₄* E_(d) 665 E_(1a)E_(iv) E₄* E_(d) 666 E_(1b)E_(iv) E₄* E_(d) 667 E_(1a)E₅E_(iv) E₄* E_(d) 668 E_(1b)E₅E_(iv) E₄* E_(d) 669 E_(1a)E_(iv)E₄ E₄* E_(d) 670 E_(1b)E_(iv)E₄ E₄* E_(d) 671 E_(1a)E₅E_(iv)E₄ E₄* E_(d) 672 E_(1b)E₅E_(iv)E₄ E₄* E_(d) 673 E_(1a) AlkL E_(d) 674 E_(1b) AlkL E_(d) 675 E_(1a)E₅ AlkL E_(d) 676 E_(1b)E₅ AlkL E_(d) 677 E_(1a)E_(i) AlkL E_(d) 678 E_(1b)E_(i) AlkL E_(d) 679 E_(1a)E_(ii) AlkL E_(d) 680 E_(1b)E_(ii) AlkL E_(d) 681 E_(1a)E_(ii)E_(iib) AlkL E_(d) 682 E_(1b)E_(ii)E_(iib) AlkL E_(d) 683 E_(1a)E₅E_(i) AlkL E_(d) 684 E_(1b)E₅E_(i) AlkL E_(d) 685 E_(1a)E₅E_(ii) AlkL E_(d) 686 E_(1b)E₅E_(ii) AlkL E_(d) 687 E_(1a)E₅E_(ii)E_(iib) AlkL E_(d) 688 E_(1b)E₅E_(ii)E_(iib) AlkL E_(d) 689 E_(1a)E₄ AlkL E_(d) 690 E_(1b)E₄ AlkL E_(d) 691 E_(1a)E₅E₄ AlkL E_(d) 692 E_(1b)E₅E₄ AlkL E_(d) 693 E_(1a)E_(i)E₄ AlkL E_(d) 694 E_(1b)E_(i)E₄ AlkL E_(d) 695 E_(1a)E_(ii)E₄ AlkL E_(d) 696 E_(1b)E_(ii)E₄ AlkL E_(d) 697 E_(1a)E_(ii)E_(iib)E₄ AlkL E_(d) 698 E_(1b)E_(ii)E_(iib)E₄ AlkL E_(d) 699 E_(1a)E₅E_(i)E₄ AlkL E_(d) 700 E_(1b)E₅E_(i)E₄ AlkL E_(d) 701 E_(1a)E₅E_(ii)E₄ AlkL E_(d) 702 E_(1b)E₅E_(ii)E₄ AlkL E_(d) 703 E_(1a)E₅E_(ii)E_(iib)E₄ AlkL E_(d) 704 E_(1b)E₅E_(ii)E_(iib)E₄ AlkL E_(d) 705 E_(1a)E_(iii) AlkL E_(d) 706 E_(1b)E_(iii) AlkL E_(d) 707 E_(1a)E₅E_(iii) AlkL E_(d) 708 E_(1b)E₅E_(iii) AlkL E_(d) 709 E_(1a)E_(iii)E₄ AlkL E_(d) 710 E_(1b)E_(iii)E₄ AlkL E_(d) 711 E_(1a)E₅E_(iii)E₄ AlkL E_(d) 712 E_(1b)E₅E_(iii)E₄ AlkL E_(d) 713 E_(1a)E_(iv) AlkL E_(d) 714 E_(1b)E_(iv) AlkL E_(d) 715 E_(1a)E₅E_(iv) AlkL E_(d) 716 E_(1b)E₅E_(iv) AlkL E_(d) 717 E_(1a)E_(iv)E₄ AlkL E_(d) 718 E_(1b)E_(iv)E₄ AlkL E_(d) 719 E_(1a)E₅E_(iv)E₄ AlkL E_(d) 720 E_(1b)E₅E_(iv)E₄ AlkL E_(d) 721 E_(1a) AlkL E₄* E_(d) 722 E_(1b) AlkL E₄* E_(d) 723 E_(1a)E₅ AlkL E₄* E_(d) 724 E_(1b)E₅ AlkL E₄* E_(d) 725 E_(1a)E_(i) AlkL E₄* E_(d) 726 E_(1b)E_(i) AlkL E₄* E_(d) 727 E_(1a)E_(ii) AlkL E₄* E_(d) 728 E_(1b)E_(ii) AlkL E₄* E_(d) 729 E_(1a)E_(ii)E_(iib) AlkL E₄* E_(d) 730 E_(1b)E_(ii)E_(iib) AlkL E₄* E_(d) 731 E_(1a)E₅E_(i) AlkL E₄* E_(d) 732 E_(1b)E₅E_(i) AlkL E₄* E_(d) 733 E_(1a)E₅E_(ii) AlkL E₄* E_(d) 734 E_(1b)E₅E_(ii) AlkL E₄* E_(d) 735 E_(1a)E₅E_(ii)E_(iib) AlkL E₄* E_(d) 736 E_(1b)E₅E_(ii)E_(iib) AlkL E₄* E_(d) 737 E_(1a)E₄ AlkL E₄* E_(d) 738 E_(1b)E₄ AlkL E₄* E_(d) 739 E_(1a)E₅E₄ AlkL E₄* E_(d) 740 E_(1b)E₅E₄ AlkL E₄* E_(d) 741 E_(1a)E_(i)E₄ AlkL E₄* E_(d) 742 E_(1b)E_(i)E₄ AlkL E₄* E_(d) 743 E_(1a)E_(ii)E₄ AlkL E₄* E_(d) 744 E_(1b)E_(ii)E₄ AlkL E₄* E_(d) 745 E_(1a)E_(ii)E_(iib)E₄ AlkL E₄* E_(d) 746 E_(1b)E_(ii)E_(iib)E₄ AlkL E₄* E_(d) 747 E_(1a)E₅E_(i)E₄ AlkL E₄* E_(d) 748 E_(1b)E₅E_(i)E₄ AlkL E₄* E_(d) 749 E_(1a)E₅E_(ii)E₄ AlkL E₄* E_(d) 750 E_(1b)E₅E_(ii)E₄ AlkL E₄* E_(d) 751 E_(1a)E₅E_(ii)E_(iib)E₄ AlkL E₄* E_(d) 752 E_(1b)E₅E_(ii)E_(iib)E₄ AlkL E₄* E_(d) 753 E_(1a)E_(iii) AlkL E₄* E_(d) 754 E_(1b)E_(iii) AlkL E₄* E_(d) 755 E_(1a)E₅E_(iii) AlkL E₄* E_(d) 756 E_(1b)E₅E_(iii) AlkL E₄* E_(d) 757 E_(1a)E_(iii)E₄ AlkL E₄* E_(d) 758 E_(1b)E_(iii)E₄ AlkL E₄* E_(d) 759 E_(1a)E₅E_(iii)E₄ AlkL E₄* E_(d) 760 E_(1b)E₅E_(iii)E₄ AlkL E₄* E_(d) 761 E_(1a)E_(iv) AlkL E₄* E_(d) 762 E_(1b)E_(iv) AlkL E₄* E_(d) 763 E_(1a)E₅E_(iv) AlkL E₄* E_(d) 764 E_(1b)E₅E_(iv) AlkL E₄* E_(d) 765 E_(1a)E_(iv)E₄ AlkL E₄* E_(d) 766 E_(1b)E_(iv)E₄ AlkL E₄* E_(d) 767 E_(1a)E₅E_(iv)E₄ AlkL E₄* E_(d) 768 E_(1b)E₅E_(iv)E₄ AlkL E₄* E_(d) 769 E_(1a) E_(e) 770 E_(1b) E_(e) 771 E_(1a)E₅ E_(e) 772 E_(1b)E₅ E_(e) 773 E_(1a)E_(i) E_(e) 774 E_(1b)E_(i) E_(e) 775 E_(1a)E_(ii) E_(e) 776 E_(1b)E_(ii) E_(e) 777 E_(1a)E_(ii)E_(iib) E_(e) 778 E_(1b)E_(ii)E_(iib) E_(e) 779 E_(1a)E₅E_(i) E_(e) 780 E_(1b)E₅E_(i) E_(e) 781 E_(1a)E₅E_(ii) E_(e) 782 E_(1b)E₅E_(ii) E_(e) 783 E_(1a)E₅E_(ii)E_(iib) E_(e) 784 E_(1b)E₅E_(ii)E_(iib) E_(e) 785 E_(1a)E₄ E_(e) 786 E_(1b)E₄ E_(e) 787 E_(1a)E₅E₄ E_(e) 788 E_(1b)E₅E₄ E_(e) 789 E_(1a)E_(i)E₄ E_(e) 790 E_(1b)E_(i)E₄ E_(e) 791 E_(1a)E_(ii)E₄ E_(e) 792 E_(1b)E_(ii)E₄ E_(e) 793 E_(1a)E_(ii)E_(iib)E₄ E_(e) 794 E_(1b)E_(ii)E_(iib)E₄ E_(e) 795 E_(1a)E₅E_(i)E₄ E_(e) 796 E_(1b)E₅E_(i)E₄ E_(e) 797 E_(1a)E₅E_(ii)E₄ E_(e) 798 E_(1b)E₅E_(ii)E₄ E_(e) 799 E_(1a)E₅E_(ii)E_(iib)E₄ E_(e) 800 E_(1b)E₅E_(ii)E_(iib)E₄ E_(e) 801 E_(1a)E_(iii) E_(e) 802 E_(1b)E_(iii) E_(e) 803 E_(1a)E₅E_(iii) E_(e) 804 E_(1b)E₅E_(iii) E_(e) 805 E_(1a)E_(iii)E₄ E_(e) 806 E_(1b)E_(iii)E₄ E_(e) 807 E_(1a)E₅E_(iii)E₄ E_(e) 808 E_(1b)E₅E_(iii)E₄ E_(e) 809 E_(1a)E_(iv) E_(e) 810 E_(1b)E_(iv) E_(e) 811 E_(1a)E₅E_(iv) E_(e) 812 E_(1b)E₅E_(iv) E_(e) 813 E_(1a)E_(iv)E₄ E_(e) 814 E_(1b)E_(iv)E₄ E_(e) 815 E_(1a)E₅E_(iv)E₄ E_(e) 816 E_(1b)E₅E_(iv)E₄ E_(e) 817 E_(1a) E₄* E_(e) 818 E_(1b) E₄* E_(e) 819 E_(1a)E₅ E₄* E_(e) 820 E_(1b)E₅ E₄* E_(e) 821 E_(1a)E_(i) E₄* E_(e) 822 E_(1b)E_(i) E₄* E_(e) 823 E_(1a)E_(ii) E₄* E_(e) 824 E_(1b)E_(ii) E₄* E_(e) 825 E_(1a)E_(ii)E_(iib) E₄* E_(e) 826 E_(1b)E_(ii)E_(iib) E₄* E_(e) 827 E_(1a)E₅E_(i) E₄* E_(e) 828 E_(1b)E₅E_(i) E₄* E_(e) 829 E_(1a)E₅E_(ii) E₄* E_(e) 830 E_(1b)E₅E_(ii) E₄* E_(e) 831 E_(1a)E₅E_(ii)E_(iib) E₄* E_(e) 832 E_(1b)E₅E_(ii)E_(iib) E₄* E_(e) 833 E_(1a)E₄ E₄* E_(e) 834 E_(1b)E₄ E₄* E_(e) 835 E_(1a)E₅E₄ E₄* E_(e) 836 E_(1b)E₅E₄ E₄* E_(e) 837 E_(1a)E_(i)E₄ E₄* E_(e) 838 E_(1b)E_(i)E₄ E₄* E_(e) 839 E_(1a)E_(ii)E₄ E₄* E_(e) 840 E_(1b)E_(ii)E₄ E₄* E_(e) 841 E_(1a)E_(ii)E_(iib)E₄ E₄* E_(e) 842 E_(1b)E_(ii)E_(iib)E₄ E₄* E_(e) 843 E_(1a)E₅E_(i)E₄ E₄* E_(e) 844 E_(1b)E₅E_(i)E₄ E₄* E_(e) 845 E_(1a)E₅E_(ii)E₄ E₄* E_(e) 846 E_(1b)E₅E_(ii)E₄ E₄* E_(e) 847 E_(1a)E₅E_(ii)E_(iib)E₄ E₄* E_(e) 848 E_(1b)E₅E_(ii)E_(iib)E₄ E₄* E_(e) 849 E_(1a)E_(iii) E₄* E_(e) 850 E_(1b)E_(iii) E₄* E_(e) 851 E_(1a)E₅E_(iii) E₄* E_(e) 852 E_(1b)E₅E_(iii) E₄* E_(e) 853 E_(1a)E_(iii)E₄ E₄* E_(e) 854 E_(1b)E_(iii)E₄ E₄* E_(e) 855 E_(1a)E₅E_(iii)E₄ E₄* E_(e) 856 E_(1b)E₅E_(iii)E₄ E₄* E_(e) 857 E_(1a)E_(iv) E₄* E_(e) 858 E_(1b)E_(iv) E₄* E_(e) 859 E_(1a)E₅E_(iv) E₄* E_(e) 860 E_(1b)E₅E_(iv) E₄* E_(e) 861 E_(1a)E_(iv)E₄ E₄* E_(e) 862 E_(1b)E_(iv)E₄ E₄* E_(e) 863 E_(1a)E₅E_(iv)E₄ E₄* E_(e) 864 E_(1b)E₅E_(iv)E₄ E₄* E_(e) 865 E_(1a) AlkL E_(e) 866 E_(1b) AlkL E_(e) 867 E_(1a)E₅ AlkL E_(e) 868 E_(1b)E₅ AlkL E_(e) 869 E_(1a)E_(i) AlkL E_(e) 870 E_(1b)E_(i) AlkL E_(e) 871 E_(1a)E_(ii) AlkL E_(e) 872 E_(1b)E_(ii) AlkL E_(e) 873 E_(1a)E_(ii)E_(iib) AlkL E_(e) 874 E_(1b)E_(ii)E_(iib) AlkL E_(e) 875 E_(1a)E₅E_(i) AlkL E_(e) 876 E_(1b)E₅E_(i) AlkL E_(e) 877 E_(1a)E₅E_(ii) AlkL E_(e) 878 E_(1b)E₅E_(ii) AlkL E_(e) 879 E_(1a)E₅E_(ii)E_(iib) AlkL E_(e) 880 E_(1b)E₅E_(ii)E_(iib) AlkL E_(e) 881 E_(1a)E₄ AlkL E_(e) 882 E_(1b)E₄ AlkL E_(e) 883 E_(1a)E₅E₄ AlkL E_(e) 884 E_(1b)E₅E₄ AlkL E_(e) 885 E_(1a)E_(i)E₄ AlkL E_(e) 886 E_(1b)E_(i)E₄ AlkL E_(e) 887 E_(1a)E_(ii)E₄ AlkL E_(e) 888 E_(1b)E_(ii)E₄ AlkL E_(e) 889 E_(1a)E_(ii)E_(iib)E₄ AlkL E_(e) 890 E_(1b)E_(ii)E_(iib)E₄ AlkL E_(e) 891 E_(1a)E₅E_(i)E₄ AlkL E_(e) 892 E_(1b)E₅E_(i)E₄ AlkL E_(e) 893 E_(1a)E₅E_(ii)E₄ AlkL E_(e) 894 E_(1b)E₅E_(ii)E₄ AlkL E_(e) 895 E_(1a)E₅E_(ii)E_(iib)E₄ AlkL E_(e) 896 E_(1b)E₅E_(ii)E_(iib)E₄ AlkL E_(e) 897 E_(1a)E_(iii) AlkL E_(e) 898 E_(1b)E_(iii) AlkL E_(e) 899 E_(1a)E₅E_(iii) AlkL E_(e) 900 E_(1b)E₅E_(iii) AlkL E_(e) 901 E_(1a)E_(iii)E₄ AlkL E_(e) 902 E_(1b)E_(iii)E₄ AlkL E_(e) 903 E_(1a)E₅E_(iii)E₄ AlkL E_(e) 904 E_(1b)E₅E_(iii)E₄ AlkL E_(e) 905 E_(1a)E_(iv) AlkL E_(e) 906 E_(1b)E_(iv) AlkL E_(e) 907 E_(1a)E₅E_(iv) AlkL E_(e) 908 E_(1b)E₅E_(iv) AlkL E_(e) 909 E_(1a)E_(iv)E₄ AlkL E_(e) 910 E_(1b)E_(iv)E₄ AlkL E_(e) 911 E_(1a)E₅E_(iv)E₄ AlkL E_(e) 912 E_(1b)E₅E_(iv)E₄ AlkL E_(e) 913 E_(1a) AlkL E₄* E_(e) 914 E_(1b) AlkL E₄* E_(e) 915 E_(1a)E₅ AlkL E₄* E_(e) 916 E_(1b)E₅ AlkL E₄* E_(e) 917 E_(1a)E_(i) AlkL E₄* E_(e) 918 E_(1b)E_(i) AlkL E₄* E_(e) 919 E_(1a)E_(ii) AlkL E₄* E_(e) 920 E_(1b)E_(ii) AlkL E₄* E_(e) 921 E_(1a)E_(ii)E_(iib) AlkL E₄* E_(e) 922 E_(1b)E_(ii)E_(iib) AlkL E₄* E_(e) 923 E_(1a)E₅E_(i) AlkL E₄* E_(e) 924 E_(1b)E₅E_(i) AlkL E₄* E_(e) 925 E_(1a)E₅E_(ii) AlkL E₄* E_(e) 926 E_(1b)E₅E_(ii) AlkL E₄* E_(e) 927 E_(1a)E₅E_(ii)E_(iib) AlkL E₄* E_(e) 928 E_(1b)E₅E_(ii)E_(iib) AlkL E₄* E_(e) 929 E_(1a)E₄ AlkL E₄* E_(e) 930 E_(1b)E₄ AlkL E₄* E_(e) 931 E_(1a)E₅E₄ AlkL E₄* E_(e) 932 E_(1b)E₅E₄ AlkL E₄* E_(e) 933 E_(1a)E_(i)E₄ AlkL E₄* E_(e) 934 E_(1b)E_(i)E₄ AlkL E₄* E_(e) 935 E_(1a)E_(ii)E₄ AlkL E₄* E_(e) 936 E_(1b)E_(ii)E₄ AlkL E₄* E_(e) 937 E_(1a)E_(ii)E_(iib)E₄ AlkL E₄* E_(e) 938 E_(1b)E_(ii)E_(iib)E₄ AlkL E₄* E_(e) 939 E_(1a)E₅E_(i)E₄ AlkL E₄* E_(e) 940 E_(1b)E₅E_(i)E₄ AlkL E₄* E_(e) 941 E_(1a)E₅E_(ii)E₄ AlkL E₄* E_(e) 942 E_(1b)E₅E_(ii)E₄ AlkL E₄* E_(e) 943 E_(1a)E₅E_(ii)E_(iib)E₄ AlkL E₄* E_(e) 944 E_(1b)E₅E_(ii)E_(iib)E₄ AlkL E₄* E_(e) 945 E_(1a)E_(iii) AlkL E₄* E_(e) 946 E_(1b)E_(iii) AlkL E₄* E_(e) 947 E_(1a)E₅E_(iii) AlkL E₄* E_(e) 948 E_(1b)E₅E_(iii) AlkL E₄* E_(e) 949 E_(1a)E_(iii)E₄ AlkL E₄* E_(e) 950 E_(1b)E_(iii)E₄ AlkL E₄* E_(e) 951 E_(1a)E₅E_(iii)E₄ AlkL E₄* E_(e) 952 E_(1b)E₅E_(iii)E₄ AlkL E₄* E_(e) 953 E_(1a)E_(iv) AlkL E₄* E_(e) 954 E_(1b)E_(iv) AlkL E₄* E_(e) 955 E_(1a)E₅E_(iv) AlkL E₄* E_(e) 956 E_(1b)E₅E_(iv) AlkL E₄* E_(e) 957 E_(1a)E_(iv)E₄ AlkL E₄* E_(e) 958 E_(1b)E_(iv)E₄ AlkL E₄* E_(e) 959 E_(1a)E₅E_(iv)E₄ AlkL E₄* E_(e) 960 E_(1b)E₅E_(iv)E₄ AlkL E₄* E_(e) 961 E_(1a) E_(f) 962 E_(1b) E_(f) 963 E_(1a)E₅ E_(f) 964 E_(1b)E₅ E_(f) 965 E_(1a)E_(i) E_(f) 966 E_(1b)E_(i) E_(f) 967 E_(1a)E_(ii) E_(f) 968 E_(1b)E_(ii) E_(f) 969 E_(1a)E_(ii)E_(iib) E_(f) 970 E_(1b)E_(ii)E_(iib) E_(f) 971 E_(1a)E₅E_(i) E_(f) 972 E_(1b)E₅E_(i) E_(f) 973 E_(1a)E₅E_(ii) E_(f) 974 E_(1b)E₅E_(ii) E_(f) 975 E_(1a)E₅E_(ii)E_(iib) E_(f) 976 E_(1b)E₅E_(ii)E_(iib) E_(f) 977 E_(1a)E₄ E_(f) 978 E_(1b)E₄ E_(f) 979 E_(1a)E₅E₄ E_(f) 980 E_(1b)E₅E₄ E_(f) 981 E_(1a)E_(i)E₄ E_(f) 982 E_(1b)E_(i)E₄ E_(f) 983 E_(1a)E_(ii)E₄ E_(f) 984 E_(1b)E_(ii)E₄ E_(f) 985 E_(1a)E_(ii)E_(iib)E₄ E_(f) 986 E_(1b)E_(ii)E_(iib)E₄ E_(f) 987 E_(1a)E₅E_(i)E₄ E_(f) 988 E_(1b)E₅E_(i)E₄ E_(f) 989 E_(1a)E₅E_(ii)E₄ E_(f) 990 E_(1b)E₅E_(ii)E₄ E_(f) 991 E_(1a)E₅E_(ii)E_(iib)E₄ E_(f) 992 E_(1b)E₅E_(ii)E_(iib)E₄ E_(f) 993 E_(1a)E_(iii) E_(f) 994 E_(1b)E_(iii) E_(f) 995 E_(1a)E₅E_(iii) E_(f) 996 E_(1b)E₅E_(iii) E_(f) 997 E_(1a)E_(iii)E₄ E_(f) 998 E_(1b)E_(iii)E₄ E_(f) 999 E_(1a)E₅E_(iii)E₄ E_(f) 1000 E_(1b)E₅E_(iii)E₄ E_(f) 1001 E_(1a)E_(iv) E_(f) 1002 E_(1b)E_(iv) E_(f) 1003 E_(1a)E₅E_(iv) E_(f) 1004 E_(1b)E₅E_(iv) E_(f) 1005 E_(1a)E_(iv)E₄ E_(f) 1006 E_(1b)E_(iv)E₄ E_(f) 1007 E_(1a)E₅E_(iv)E₄ E_(f) 1008 E_(1b)E₅E_(iv)E₄ E_(f) 1009 E_(1a) E₄* E_(f) 1010 E_(1b) E₄* E_(f) 1011 E_(1a)E₅ E₄* E_(f) 1012 E_(1b)E₅ E₄* E_(f) 1013 E_(1a)E_(i) E₄* E_(f) 1014 E_(1b)E_(i) E₄* E_(f) 1015 E_(1a)E_(ii) E₄* E_(f) 1016 E_(1b)E_(ii) E₄* E_(f) 1017 E_(1a)E_(ii)E_(iib) E₄* E_(f) 1018 E_(1b)E_(ii)E_(iib) E₄* E_(f) 1019 E_(1a)E₅E_(i) E₄* E_(f) 1020 E_(1b)E₅E_(i) E₄* E_(f) 1021 E_(1a)E₅E_(ii) E₄* E_(f) 1022 E_(1b)E₅E_(ii) E₄* E_(f) 1023 E_(1a)E₅E_(ii)E_(iib) E₄* E_(f) 1024 E_(1b)E₅E_(ii)E_(iib) E₄* E_(f) 1025 E_(1a)E₄ E₄* E_(f) 1026 E_(1b)E₄ E₄* E_(f) 1027 E_(1a)E₅E₄ E₄* E_(f) 1028 E_(1b)E₅E₄ E₄* E_(f) 1029 E_(1a)E_(i)E₄ E₄* E_(f) 1030 E_(1b)E_(i)E₄ E₄* E_(f) 1031 E_(1a)E_(ii)E₄ E₄* E_(f) 1032 E_(1b)E_(ii)E₄ E₄* E_(f) 1033 E_(1a)E_(ii)E_(iib)E₄ E₄* E_(f) 1034 E_(1b)E_(ii)E_(iib)E₄ E₄* E_(f) 1035 E_(1a)E₅E_(i)E₄ E₄* E_(f) 1036 E_(1b)E₅E_(i)E₄ E₄* E_(f) 1037 E_(1a)E₅E_(ii)E₄ E₄* E_(f) 1038 E_(1b)E₅E_(ii)E₄ E₄* E_(f) 1039 E_(1a)E₅E_(ii)E_(iib)E₄ E₄* E_(f) 1040 E_(1b)E₅E_(ii)E_(iib)E₄ E₄* E_(f) 1041 E_(1a)E_(iii) E₄* E_(f) 1042 E_(1b)E_(iii) E₄* E_(f) 1043 E_(1a)E₅E_(iii) E₄* E_(f) 1044 E_(1b)E₅E_(iii) E₄* E_(f) 1045 E_(1a)E_(iii)E₄ E₄* E_(f) 1046 E_(1b)E_(iii)E₄ E₄* E_(f) 1047 E_(1a)E₅E_(iii)E₄ E₄* E_(f) 1048 E_(1b)E₅E_(iii)E₄ E₄* E_(f) 1049 E_(1a)E_(iv) E₄* E_(f) 1050 E_(1b)E_(iv) E₄* E_(f) 1051 E_(1a)E₅E_(iv) E₄* E_(f) 1052 E_(1b)E₅E_(iv) E₄* E_(f) 1053 E_(1a)E_(iv)E₄ E₄* E_(f) 1054 E_(1b)E_(iv)E₄ E₄* E_(f) 1055 E_(1a)E₅E_(iv)E₄ E₄* E_(f) 1056 E_(1b)E₅E_(iv)E₄ E₄* E_(f) 1057 E_(1a) AlkL E_(f) 1058 E_(1b) AlkL E_(f) 1059 E_(1a)E₅ AlkL E_(f) 1060 E_(1b)E₅ AlkL E_(f) 1061 E_(1a)E_(i) AlkL E_(f) 1062 E_(1b)E_(i) AlkL E_(f) 1063 E_(1a)E_(ii) AlkL E_(f) 1064 E_(1b)E_(ii) AlkL E_(f) 1065 E_(1a)E_(ii)E_(iib) AlkL E_(f) 1066 E_(1b)E_(ii)E_(iib) AlkL E_(f) 1067 E_(1a)E₅E_(i) AlkL E_(f) 1068 E_(1b)E₅E_(i) AlkL E_(f) 1069 E_(1a)E₅E_(ii) AlkL E_(f) 1070 E_(1b)E₅E_(ii) AlkL E_(f) 1071 E_(1a)E₅E_(ii)E_(iib) AlkL E_(f) 1072 E_(1b)E₅E_(ii)E_(iib) AlkL E_(f) 1073 E_(1a)E₄ AlkL E_(f) 1074 E_(1b)E₄ AlkL E_(f) 1075 E_(1a)E₅E₄ AlkL E_(f) 1076 E_(1b)E₅E₄ AlkL E_(f) 1077 E_(1a)E_(i)E₄ AlkL E_(f) 1078 E_(1b)E_(i)E₄ AlkL E_(f) 1079 E_(1a)E_(ii)E₄ AlkL E_(f) 1080 E_(1b)E_(ii)E₄ AlkL E_(f) 1081 E_(1a)E_(ii)E_(iib)E₄ AlkL E_(f) 1082 E_(1b)E_(ii)E_(iib)E₄ AlkL E_(f) 1083 E_(1a)E₅E_(i)E₄ AlkL E_(f) 1084 E_(1b)E₅E_(i)E₄ AlkL E_(f) 1085 E_(1a)E₅E_(ii)E₄ AlkL E_(f) 1086 E_(1b)E₅E_(ii)E₄ AlkL E_(f) 1087 E_(1a)E₅E_(ii)E_(iib)E₄ AlkL E_(f) 1088 E_(1b)E₅E_(ii)E_(iib)E₄ AlkL E_(f) 1089 E_(1a)E_(iii) AlkL E_(f) 1090 E_(1b)E_(iii) AlkL E_(f) 1091 E_(1a)E₅E_(iii) AlkL E_(f) 1092 E_(1b)E₅E_(iii) AlkL E_(f) 1093 E_(1a)E_(iii)E₄ AlkL E_(f) 1094 E_(1b)E_(iii)E₄ AlkL E_(f) 1095 E_(1a)E₅E_(iii)E₄ AlkL E_(f) 1096 E_(1b)E₅E_(iii)E₄ AlkL E_(f) 1097 E_(1a)E_(iv) AlkL E_(f) 1098 E_(1b)E_(iv) AlkL E_(f) 1099 E_(1a)E₅E_(iv) AlkL E_(f) 1100 E_(1b)E₅E_(iv) AlkL E_(f) 1101 E_(1a)E_(iv)E₄ AlkL E_(f) 1102 E_(1b)E_(iv)E₄ AlkL E_(f) 1103 E_(1a)E₅E_(iv)E₄ AlkL E_(f) 1104 E_(1b)E₅E_(iv)E₄ AlkL E_(f) 1105 E_(1a) AlkL E₄* E_(f) 1106 E_(1b) AlkL E₄* E_(f) 1107 E_(1a)E₅ AlkL E₄* E_(f) 1108 E_(1b)E₅ AlkL E₄* E_(f) 1109 E_(1a)E_(i) AlkL E₄* E_(f) 1110 E_(1b)E_(i) AlkL E₄* E_(f) 1111 E_(1a)E_(ii) AlkL E₄* E_(f) 1112 E_(1b)E_(ii) AlkL E₄* E_(f) 1113 E_(1a)E_(ii)E_(iib) AlkL E₄* E_(f) 1114 E_(1b)E_(ii)E_(iib) AlkL E₄* E_(f) 1115 E_(1a)E₅E_(i) AlkL E₄* E_(f) 1116 E_(1b)E₅E_(i) AlkL E₄* E_(f) 1117 E_(1a)E₅E_(ii) AlkL E₄* E_(f) 1118 E_(1b)E₅E_(ii) AlkL E₄* E_(f) 1119 E_(1a)E₅E_(ii)E_(iib) AlkL E₄* E_(f) 1120 E_(1b)E₅E_(ii)E_(iib) AlkL E₄* E_(f) 1121 E_(1a)E₄ AlkL E₄* E_(f) 1122 E_(1b)E₄ AlkL E₄* E_(f) 1123 E_(1a)E₅E₄ AlkL E₄* E_(f) 1124 E_(1b)E₅E₄ AlkL E₄* E_(f) 1125 E_(1a)E_(i)E₄ AlkL E₄* E_(f) 1126 E_(1b)E_(i)E₄ AlkL E₄* E_(f) 1127 E_(1a)E_(ii)E₄ AlkL E₄* E_(f) 1128 E_(1b)E_(ii)E₄ AlkL E₄* E_(f) 1129 E_(1a)E_(ii)E_(iib)E₄ AlkL E₄* E_(f) 1130 E_(1b)E_(ii)E_(iib)E₄ AlkL E₄* E_(f) 1131 E_(1a)E₅E_(i)E₄ AlkL E₄* E_(f) 1132 E_(1b)E₅E_(i)E₄ AlkL E₄* E_(f) 1133 E_(1a)E₅E_(ii)E₄ AlkL E₄* E_(f) 1134 E_(1b)E₅E_(ii)E₄ AlkL E₄* E_(f) 1135 E_(1a)E₅E_(ii)E_(iib)E₄ AlkL E₄* E_(f) 1136 E_(1b)E₅E_(ii)E_(iib)E₄ AlkL E₄* E_(f) 1137 E_(1a)E_(iii) AlkL E₄* E_(f) 1138 E_(1b)E_(iii) AlkL E₄* E_(f) 1139 E_(1a)E₅E_(iii) AlkL E₄* E_(f) 1140 E_(1b)E₅E_(iii) AlkL E₄* E_(f) 1141 E_(1a)E_(iii)E₄ AlkL E₄* E_(f) 1142 E_(1b)E_(iii)E₄ AlkL E₄* E_(f) 1143 E_(1a)E₅E_(iii)E₄ AlkL E₄* E_(f) 1144 E_(1b)E₅E_(iii)E₄ AlkL E₄* E_(f) 1145 E_(1a)E_(iv) AlkL E₄* E_(f) 1146 E_(1b)E_(iv) AlkL E₄* E_(f) 1147 E_(1a)E₅E_(iv) AlkL E₄* E_(f) 1148 E_(1b)E₅E_(iv) AlkL E₄* E_(f) 1149 E_(1a)E_(iv)E₄ AlkL E₄* E_(f) 1150 E_(1b)E_(iv)E₄ AlkL E₄* E_(f) 1151 E_(1a)E₅E_(iv)E₄ AlkL E₄* E_(f) 1152 E_(1b)E₅E_(iv)E₄ AlkL E₄* E_(f)

Microorganisms quite especially preferred according to the invention (abbreviated as MO) are outstandingly suitable for the production of ω-carboxycarboxylate esters and have increased or decreased enzyme activities (abbreviated as E) described in the following table, where these can in addition advantageously be combined with an increased enzyme activity compared to the wild type of the microorganism, which is described for the 3-ketoacyl-ACP (Acyl Carrrier Protein) synthase III (EC 2.3.1.41), in particular that from plants, preferably that from plants the seeds whereof contain fatty acids with alkyl residues shorter than 14 C atoms, and particularly preferably that from plants of the genera Cuphea, Elaeis, Cocos, Umbellularia and Cinnamomum and gene products selected from AccA, AccB, AccC, AccD, AceE, AceF, Lpd, AcpP, FabA, FabB, FabD, FabF, FabG, FabH, Fabl, FabZ, PanD, PanK, UdhA, PntA or PntB.

Any combinations of at least two of these enzyme activities can advantageously be increased.

In addition, moreover, it can be advantageous if the microorganism is provided with a lower enzyme activity compared to the wild type of the microorganism, which is described for the gene products selected from TdcE, PflA, PflB, PflC, PflD, PoxB, YgfG, AckA, AckB, TdcD, Pta, LdhA, AdhE, MgsA, FdnG, FdnH, FdnI, FdhF, FdoG, FdoH, FdoI, PrpC, PrpD, PrpF, PrpB, TdcD, Pdc, PorA, PorB, PorC, PorD, AlsS, IlvB, IlvM, IlvN, IlvG, IlyI, IlvH, AlsD, ButB, Thl, ThlA, ThlB, PhaA, PhaB, Crt, BdhA, BdhB, Adc, Adh, CtfB, AtoA, AtoD, LdhL, GltA, FabR, FhuA, Dld, LldA or LldP, singly or in any combination.

MO E increased E decreased 1 E_(1a) E_(v)E_(vi) 2 E_(1b) E_(v)E_(vi) 3 E_(1a)E₅ E_(v)E_(vi) 4 E_(1b)E₅ E_(v)E_(vi) 5 E_(1a)E_(i) E_(v)E_(vi) 6 E_(1b)E_(i) E_(v)E_(vi) 7 E_(1a)E_(ii) E_(v)E_(vi) 8 E_(1b)E_(ii) E_(v)E_(vi) 9 E_(1a)E_(ii)E_(iib) E_(v)E_(vi) 10 E_(1b)E_(ii)E_(iib) E_(v)E_(vi) 11 E_(1a)E₅E_(i) E_(v)E_(vi) 12 E_(1b)E₅E_(i) E_(v)E_(vi) 13 E_(1a)E₅E_(ii) E_(v)E_(vi) 14 E_(1b)E₅E_(ii) E_(v)E_(vi) 15 E_(1a)E₅E_(ii)E_(iib) E_(v)E_(vi) 16 E_(1b)E₅E_(ii)E_(iib) E_(v)E_(vi) 17 E_(1a)E₄ E_(v)E_(vi) 18 E_(1b)E₄ E_(v)E_(vi) 19 E_(1a)E₅E₄ E_(v)E_(vi) 20 E_(1b)E₅E₄ E_(v)E_(vi) 21 E_(1a)E_(i)E₄ E_(v)E_(vi) 22 E_(1b)E_(i)E₄ E_(v)E_(vi) 23 E_(1a)E_(ii)E₄ E_(v)E_(vi) 24 E_(1b)E_(ii)E₄ E_(v)E_(vi) 25 E_(1a)E_(ii)E_(iib)E₄ E_(v)E_(vi) 26 E_(1b)E_(ii)E_(iib)E₄ E_(v)E_(vi) 27 E_(1a)E₅E_(i)E₄ E_(v)E_(vi) 28 E_(1b)E₅E_(i)E₄ E_(v)E_(vi) 29 E_(1a)E₅E_(ii)E₄ E_(v)E_(vi) 30 E_(1b)E₅E_(ii)E₄ E_(v)E_(vi) 31 E_(1a)E₅E_(ii)E_(iib)E₄ E_(v)E_(vi) 32 E_(1b)E₅E_(ii)E_(iib)E₄ E_(v)E_(vi) 33 E_(1a)E_(iii) E_(v)E_(vi) 34 E_(1b)E_(iii) E_(v)E_(vi) 35 E_(1a)E₅E_(iii) E_(v)E_(vi) 36 E_(1b)E₅E_(iii) E_(v)E_(vi) 37 E_(1a)E_(iii)E₄ E_(v)E_(vi) 38 E_(1b)E_(iii)E₄ E_(v)E_(vi) 39 E_(1a)E₅E_(iii)E₄ E_(v)E_(vi) 40 E_(1b)E₅E_(iii)E₄ E_(v)E_(vi) 41 E_(1a)E_(iv) E_(v)E_(vi) 42 E_(1b)E_(iv) E_(v)E_(vi) 43 E_(1a)E₅E_(iv) E_(v)E_(vi) 44 E_(1b)E₅E_(iv) E_(v)E_(vi) 45 E_(1a)E_(iv)E₄ E_(v)E_(vi) 46 E_(1b)E_(iv)E₄ E_(v)E_(vi) 47 E_(1a)E₅E_(iv)E₄ E_(v)E_(vi) 48 E_(1b)E₅E_(iv)E₄ E_(v)E_(vi) 49 E_(1a) E_(v)E_(vi) E₄* 50 E_(1b) E_(v)E_(vi) E₄* 51 E_(1a)E₅ E_(v)E_(vi) E₄* 52 E_(1b)E₅ E_(v)E_(vi) E₄* 53 E_(1a)E_(i) E_(v)E_(vi) E₄* 54 E_(1b)E_(i) E_(v)E_(vi) E₄* 55 E_(1a)E_(ii) E_(v)E_(vi) E₄* 56 E_(1b)E_(ii) E_(v)E_(vi) E₄* 57 E_(1a)E_(ii)E_(iib) E_(v)E_(vi) E₄* 58 E_(1b)E_(ii)E_(iib) E_(v)E_(vi) E₄* 59 E_(1a)E₅E_(i) E_(v)E_(vi) E₄* 60 E_(1b)E₅E_(i) E_(v)E_(vi) E₄* 61 E_(1a)E₅E_(ii) E_(v)E_(vi) E₄* 62 E_(1b)E₅E_(ii) E_(v)E_(vi) E₄* 63 E_(1a)E₅E_(ii)E_(iib) E_(v)E_(vi) E₄* 64 E_(1b)E₅E_(ii)E_(iib) E_(v)E_(vi) E₄* 65 E_(1a)E₄ E_(v)E_(vi) E₄* 66 E_(1b)E₄ E_(v)E_(vi) E₄* 67 E_(1a)E₅E₄ E_(v)E_(vi) E₄* 68 E_(1b)E₅E₄ E_(v)E_(vi) E₄* 69 E_(1a)E_(i)E₄ E_(v)E_(vi) E₄* 70 E_(1b)E_(i)E₄ E_(v)E_(vi) E₄* 71 E_(1a)E_(ii)E₄ E_(v)E_(vi) E₄* 72 E_(1b)E_(ii)E₄ E_(v)E_(vi) E₄* 73 E_(1a)E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* 74 E_(1b)E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* 75 E_(1a)E₅E_(i)E₄ E_(v)E_(vi) E₄* 76 E_(1b)E₅E_(i)E₄ E_(v)E_(vi) E₄* 77 E_(1a)E₅E_(ii)E₄ E_(v)E_(vi) E₄* 78 E_(1b)E₅E_(ii)E₄ E_(v)E_(vi) E₄* 79 E_(1a)E₅E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* 80 E_(1b)E₅E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* 81 E_(1a)E_(iii) E_(v)E_(vi) E₄* 82 E_(1b)E_(iii) E_(v)E_(vi) E₄* 83 E_(1a)E₅E_(iii) E_(v)E_(vi) E₄* 84 E_(1b)E₅E_(iii) E_(v)E_(vi) E₄* 85 E_(1a)E_(iii)E₄ E_(v)E_(vi) E₄* 86 E_(1b)E_(iii)E₄ E_(v)E_(vi) E₄* 87 E_(1a)E₅E_(iii)E₄ E_(v)E_(vi) E₄* 88 E_(1b)E₅E_(iii)E₄ E_(v)E_(vi) E₄* 89 E_(1a)E_(iv) E_(v)E_(vi) E₄* 90 E_(1b)E_(iv) E_(v)E_(vi) E₄* 91 E_(1a)E₅E_(iv) E_(v)E_(vi) E₄* 92 E_(1b)E₅E_(iv) E_(v)E_(vi) E₄* 93 E_(1a)E_(iv)E₄ E_(v)E_(vi) E₄* 94 E_(1b)E_(iv)E₄ E_(v)E_(vi) E₄* 95 E_(1a)E₅E_(iv)E₄ E_(v)E_(vi) E₄* 96 E_(1b)E₅E_(iv)E₄ E_(v)E_(vi) E₄* 97 E_(1a) AlkLE_(v)E_(vi) 98 E_(1b) AlkLE_(v)E_(vi) 99 E_(1a)E₅ AlkLE_(v)E_(vi) 100 E_(1b)E₅ AlkLE_(v)E_(vi) 101 E_(1a)E_(i) AlkLE_(v)E_(vi) 102 E_(1b)E_(i) AlkLE_(v)E_(vi) 103 E_(1a)E_(ii) AlkLE_(v)E_(vi) 104 E_(1b)E_(ii) AlkLE_(v)E_(vi) 105 E_(1a)E_(ii)E_(iib) AlkLE_(v)E_(vi) 106 E_(1b)E_(ii)E_(iib) AlkLE_(v)E_(vi) 107 E_(1a)E₅E_(i) AlkLE_(v)E_(vi) 108 E_(1b)E₅E_(i) AlkLE_(v)E_(vi) 109 E_(1a)E₅E_(ii) AlkLE_(v)E_(vi) 110 E_(1b)E₅E_(ii) AlkLE_(v)E_(vi) 111 E_(1a)E₅E_(ii)E_(iib) AlkLE_(v)E_(vi) 112 E_(1b)E₅E_(ii)E_(iib) AlkLE_(v)E_(vi) 113 E_(1a)E₄ AlkLE_(v)E_(vi) 114 E_(1b)E₄ AlkLE_(v)E_(vi) 115 E_(1a)E₅E₄ AlkLE_(v)E_(vi) 116 E_(1b)E₅E₄ AlkLE_(v)E_(vi) 117 E_(1a)E_(i)E₄ AlkLE_(v)E_(vi) 118 E_(1b)E_(i)E₄ AlkLE_(v)E_(vi) 119 E_(1a)E_(ii)E₄ AlkLE_(v)E_(vi) 120 E_(1b)E_(ii)E₄ AlkLE_(v)E_(vi) 121 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) 122 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) 123 E_(1a)E₅E_(i)E₄ AlkLE_(v)E_(vi) 124 E_(1b)E₅E_(i)E₄ AlkLE_(v)E_(vi) 125 E_(1a)E₅E_(ii)E₄ AlkLE_(v)E_(vi) 126 E_(1b)E₅E_(ii)E₄ AlkLE_(v)E_(vi) 127 E_(1a)E₅E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) 128 E_(1b)E₅E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) 129 E_(1a)E_(iii) AlkLE_(v)E_(vi) 130 E_(1b)E_(iii) AlkLE_(v)E_(vi) 131 E_(1a)E₅E_(iii) AlkLE_(v)E_(vi) 132 E_(1b)E₅E_(iii) AlkLE_(v)E_(vi) 133 E_(1a)E_(iii)E₄ AlkLE_(v)E_(vi) 134 E_(1b)E_(iii)E₄ AlkLE_(v)E_(vi) 135 E_(1a)E₅E_(iii)E₄ AlkLE_(v)E_(vi) 136 E_(1b)E₅E_(iii)E₄ AlkLE_(v)E_(vi) 137 E_(1a)E_(iv) AlkLE_(v)E_(vi) 138 E_(1b)E_(iv) AlkLE_(v)E_(vi) 139 E_(1a)E₅E_(iv) AlkLE_(v)E_(vi) 140 E_(1b)E₅E_(iv) AlkLE_(v)E_(vi) 141 E_(1a)E_(iv)E₄ AlkLE_(v)E_(vi) 142 E_(1b)E_(iv)E₄ AlkLE_(v)E_(vi) 143 E_(1a)E₅E_(iv)E₄ AlkLE_(v)E_(vi) 144 E_(1b)E₅E_(iv)E₄ AlkLE_(v)E_(vi) 145 E_(1a) AlkLE_(v)E_(vi) E₄* 146 E_(1b) AlkLE_(v)E_(vi) E₄* 147 E_(1a)E₅ AlkLE_(v)E_(vi) E₄* 148 E_(1b)E₅ AlkLE_(v)E_(vi) E₄* 149 E_(1a)E_(i) AlkLE_(v)E_(vi) E₄* 150 E_(1b)E_(i) AlkLE_(v)E_(vi) E₄* 151 E_(1a)E_(ii) AlkLE_(v)E_(vi) E₄* 152 E_(1b)E_(ii) AlkLE_(v)E_(vi) E₄* 153 E_(1a)E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* 154 E_(1b)E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* 155 E_(1a)E₅E_(i) AlkLE_(v)E_(vi) E₄* 156 E_(1b)E₅E_(i) AlkLE_(v)E_(vi) E₄* 157 E_(1a)E₅E_(ii) AlkLE_(v)E_(vi) E₄* 158 E_(1b)E₅E_(ii) AlkLE_(v)E_(vi) E₄* 159 E_(1a)E₅E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* 160 E_(1b)E₅E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* 161 E_(1a)E₄ AlkLE_(v)E_(vi) E₄* 162 E_(1b)E₄ AlkLE_(v)E_(vi) E₄* 163 E_(1a)E₅E₄ AlkLE_(v)E_(vi) E₄* 164 E_(1b)E₅E₄ AlkLE_(v)E_(vi) E₄* 165 E_(1a)E_(i)E₄ AlkLE_(v)E_(vi) E₄* 166 E_(1b)E_(i)E₄ AlkLE_(v)E_(vi) E₄* 167 E_(1a)E_(ii)E₄ AlkLE_(v)E_(vi) E₄* 168 E_(1b)E_(ii)E₄ AlkLE_(v)E_(vi) E₄* 169 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* 170 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* 171 E_(1a)E₅E_(i)E₄ AlkLE_(v)E_(vi) E₄* 172 E_(1b)E₅E_(i)E₄ AlkLE_(v)E_(vi) E₄* 173 E_(1a)E₅E_(ii)E₄ AlkLE_(v)E_(vi) E₄* 174 E_(1b)E₅E_(ii)E₄ AlkLE_(v)E_(vi) E₄* 175 E_(1a)E₅E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* 176 E_(1b)E₅E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* 177 E_(1a)E_(iii) AlkLE_(v)E_(vi) E₄* 178 E_(1b)E_(iii) AlkLE_(v)E_(vi) E₄* 179 E_(1a)E₅E_(iii) AlkLE_(v)E_(vi) E₄* 180 E_(1b)E₅E_(iii) AlkLE_(v)E_(vi) E₄* 181 E_(1a)E_(iii)E₄ AlkLE_(v)E_(vi) E₄* 182 E_(1b)E_(iii)E₄ AlkLE_(v)E_(vi) E₄* 183 E_(1a)E₅E_(iii)E₄ AlkLE_(v)E_(vi) E₄* 184 E_(1b)E₅E_(iii)E₄ AlkLE_(v)E_(vi) E₄* 185 E_(1a)E_(iv) AlkLE_(v)E_(vi) E₄* 186 E_(1b)E_(iv) AlkLE_(v)E_(vi) E₄* 187 E_(1a)E₅E_(iv) AlkLE_(v)E_(vi) E₄* 188 E_(1b)E₅E_(iv) AlkLE_(v)E_(vi) E₄* 189 E_(1a)E_(iv)E₄ AlkLE_(v)E_(vi) E₄* 190 E_(1b)E_(iv)E₄ AlkLE_(v)E_(vi) E₄* 191 E_(1a)E₅E_(iv)E₄ AlkLE_(v)E_(vi) E₄* 192 E_(1b)E₅E_(iv)E₄ AlkLE_(v)E_(vi) E₄* 193 E_(1a) E_(v)E_(vi) E_(a) 194 E_(1b) E_(v)E_(vi) E_(a) 195 E_(1a)E₅ E_(v)E_(vi) E_(a) 196 E_(1b)E₅ E_(v)E_(vi) E_(a) 197 E_(1a)E_(i) E_(v)E_(vi) E_(a) 198 E_(1b)E_(i) E_(v)E_(vi) E_(a) 199 E_(1a)E_(ii) E_(v)E_(vi) E_(a) 200 E_(1b)E_(ii) E_(v)E_(vi) E_(a) 201 E_(1a)E_(ii)E_(iib) E_(v)E_(vi) E_(a) 202 E_(1b)E_(ii)E_(iib) E_(v)E_(vi) E_(a) 203 E_(1a)E₅E_(i) E_(v)E_(vi) E_(a) 204 E_(1b)E₅E_(i) E_(v)E_(vi) E_(a) 205 E_(1a)E₅E_(ii) E_(v)E_(vi) E_(a) 206 E_(1b)E₅E_(ii) E_(v)E_(vi) E_(a) 207 E_(1a)E₅E_(ii)E_(iib) E_(v)E_(vi) E_(a) 208 E_(1b)E₅E_(ii)E_(iib) E_(v)E_(vi) E_(a) 209 E_(1a)E₄ E_(v)E_(vi) E_(a) 210 E_(1b)E₄ E_(v)E_(vi) E_(a) 211 E_(1a)E₅E₄ E_(v)E_(vi) E_(a) 212 E_(1b)E₅E₄ E_(v)E_(vi) E_(a) 213 E_(1a)E_(i)E₄ E_(v)E_(vi) E_(a) 214 E_(1b)E_(i)E₄ E_(v)E_(vi) E_(a) 215 E_(1a)E_(ii)E₄ E_(v)E_(vi) E_(a) 216 E_(1b)E_(ii)E₄ E_(v)E_(vi) E_(a) 217 E_(1a)E_(ii)E_(iib)E₄ E_(v)E_(vi) E_(a) 218 E_(1b)E_(ii)E_(iib)E₄ E_(v)E_(vi) E_(a) 219 E_(1a)E₅E_(i)E₄ E_(v)E_(vi) E_(a) 220 E_(1b)E₅E_(i)E₄ E_(v)E_(vi) E_(a) 221 E_(1a)E₅E_(ii)E₄ E_(v)E_(vi) E_(a) 222 E_(1b)E₅E_(ii)E₄ E_(v)E_(vi) E_(a) 223 E_(1a)E₅E_(ii)E_(iib)E₄ E_(v)E_(vi) E_(a) 224 E_(1b)E₅E_(ii)E_(iib)E₄ E_(v)E_(vi) E_(a) 225 E_(1a)E_(iii) E_(v)E_(vi) E_(a) 226 E_(1b)E_(iii) E_(v)E_(vi) E_(a) 227 E_(1a)E₅E_(iii) E_(v)E_(vi) E_(a) 228 E_(1b)E₅E_(iii) E_(v)E_(vi) E_(a) 229 E_(1a)E_(iii)E₄ E_(v)E_(vi) E_(a) 230 E_(1b)E_(iii)E₄ E_(v)E_(vi) E_(a) 231 E_(1a)E₅E_(iii)E₄ E_(v)E_(vi) E_(a) 232 E_(1b)E₅E_(iii)E₄ E_(v)E_(vi) E_(a) 233 E_(1a)E_(iv) E_(v)E_(vi) E_(a) 234 E_(1b)E_(iv) E_(v)E_(vi) E_(a) 235 E_(1a)E₅E_(iv) E_(v)E_(vi) E_(a) 236 E_(1b)E₅E_(iv) E_(v)E_(vi) E_(a) 237 E_(1a)E_(iv)E₄ E_(v)E_(vi) E_(a) 238 E_(1b)E_(iv)E₄ E_(v)E_(vi) E_(a) 239 E_(1a)E₅E_(iv)E₄ E_(v)E_(vi) E_(a) 240 E_(1b)E₅E_(iv)E₄ E_(v)E_(vi) E_(a) 241 E_(1a) E_(v)E_(vi) E₄* E_(a) 242 E_(1b) E_(v)E_(vi) E₄* E_(a) 243 E_(1a)E₅ E_(v)E_(vi) E₄* E_(a) 244 E_(1b)E₅ E_(v)E_(vi) E₄* E_(a) 245 E_(1a)E_(i) E_(v)E_(vi) E₄* E_(a) 246 E_(1b)E_(i) E_(v)E_(vi) E₄* E_(a) 247 E_(1a)E_(ii) E_(v)E_(vi) E₄* E_(a) 248 E_(1b)E_(ii) E_(v)E_(vi) E₄* E_(a) 249 E_(1a)E_(ii)E_(iib) E_(v)E_(vi) E₄* E_(a) 250 E_(1b)E_(ii)E_(iib) E_(v)E_(vi) E₄* E_(a) 251 E_(1a)E₅E_(i) E_(v)E_(vi) E₄* E_(a) 252 E_(1b)E₅E_(i) E_(v)E_(vi) E₄* E_(a) 253 E_(1a)E₅E_(ii) E_(v)E_(vi) E₄* E_(a) 254 E_(1b)E₅E_(ii) E_(v)E_(vi) E₄* E_(a) 255 E_(1a)E₅E_(ii)E_(iib) E_(v)E_(vi) E₄* E_(a) 256 E_(1b)E₅E_(ii)E_(iib) E_(v)E_(vi) E₄* E_(a) 257 E_(1a)E₄ E_(v)E_(vi) E₄* E_(a) 258 E_(1b)E₄ E_(v)E_(vi) E₄* E_(a) 259 E_(1a)E₅E₄ E_(v)E_(vi) E₄* E_(a) 260 E_(1b)E₅E₄ E_(v)E_(vi) E₄* E_(a) 261 E_(1a)E_(i)E₄ E_(v)E_(vi) E₄* E_(a) 262 E_(1b)E_(i)E₄ E_(v)E_(vi) E₄* E_(a) 263 E_(1a)E_(ii)E₄ E_(v)E_(vi) E₄* E_(a) 264 E_(1b)E_(ii)E₄ E_(v)E_(vi) E₄* E_(a) 265 E_(1a)E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* E_(a) 266 E_(1b)E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* E_(a) 267 E_(1a)E₅E_(i)E₄ E_(v)E_(vi) E₄* E_(a) 268 E_(1b)E₅E_(i)E₄ E_(v)E_(vi) E₄* E_(a) 269 E_(1a)E₅E_(ii)E₄ E_(v)E_(vi) E₄* E_(a) 270 E_(1b)E₅E_(ii)E₄ E_(v)E_(vi) E₄* E_(a) 271 E_(1a)E₅E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* E_(a) 272 E_(1b)E₅E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* E_(a) 273 E_(1a)E_(iii) E_(v)E_(vi) E₄* E_(a) 274 E_(1b)E_(iii) E_(v)E_(vi) E₄* E_(a) 275 E_(1a)E₅E_(iii) E_(v)E_(vi) E₄* E_(a) 276 E_(1b)E₅E_(iii) E_(v)E_(vi) E₄* E_(a) 277 E_(1a)E_(iii)E₄ E_(v)E_(vi) E₄* E_(a) 278 E_(1b)E_(iii)E₄ E_(v)E_(vi) E₄* E_(a) 279 E_(1a)E₅E_(iii)E₄ E_(v)E_(vi) E₄* E_(a) 280 E_(1b)E₅E_(iii)E₄ E_(v)E_(vi) E₄* E_(a) 281 E_(1a)E_(iv) E_(v)E_(vi) E₄* E_(a) 282 E_(1b)E_(iv) E_(v)E_(vi) E₄* E_(a) 283 E_(1a)E₅E_(iv) E_(v)E_(vi) E₄* E_(a) 284 E_(1b)E₅E_(iv) E_(v)E_(vi) E₄* E_(a) 285 E_(1a)E_(iv)E₄ E_(v)E_(vi) E₄* E_(a) 286 E_(1b)E_(iv)E₄ E_(v)E_(vi) E₄* E_(a) 287 E_(1a)E₅E_(iv)E₄ E_(v)E_(vi) E₄* E_(a) 288 E_(1b)E₅E_(iv)E₄ E_(v)E_(vi) E₄* E_(a) 289 E_(1a) AlkLE_(v)E_(vi) E_(a) 290 E_(1b) AlkLE_(v)E_(vi) E_(a) 291 E_(1a)E₅ AlkLE_(v)E_(vi) E_(a) 292 E_(1b)E₅ AlkLE_(v)E_(vi) E_(a) 293 E_(1a)E_(i) AlkLE_(v)E_(vi) E_(a) 294 E_(1b)E_(i) AlkLE_(v)E_(vi) E_(a) 295 E_(1a)E_(ii) AlkLE_(v)E_(vi) E_(a) 296 E_(1b)E_(ii) AlkLE_(v)E_(vi) E_(a) 297 E_(1a)E_(ii)E_(iib) AlkLE_(v)E_(vi) E_(a) 298 E_(1b)E_(ii)E_(iib) AlkLE_(v)E_(vi) E_(a) 299 E_(1a)E₅E_(i) AlkLE_(v)E_(vi) E_(a) 300 E_(1b)E₅E_(i) AlkLE_(v)E_(vi) E_(a) 301 E_(1a)E₅E_(ii) AlkLE_(v)E_(vi) E_(a) 302 E_(1b)E₅E_(ii) AlkLE_(v)E_(vi) E_(a) 303 E_(1a)E₅E_(ii)E_(iib) AlkLE_(v)E_(vi) E_(a) 304 E_(1b)E₅E_(ii)E_(iib) AlkLE_(v)E_(vi) E_(a) 305 E_(1a)E₄ AlkLE_(v)E_(vi) E_(a) 306 E_(1b)E₄ AlkLE_(v)E_(vi) E_(a) 307 E_(1a)E₅E₄ AlkLE_(v)E_(vi) E_(a) 308 E_(1b)E₅E₄ AlkLE_(v)E_(vi) E_(a) 309 E_(1a)E_(i)E₄ AlkLE_(v)E_(vi) E_(a) 310 E_(1b)E_(i)E₄ AlkLE_(v)E_(vi) E_(a) 311 E_(1a)E_(ii)E₄ AlkLE_(v)E_(vi) E_(a) 312 E_(1b)E_(ii)E₄ AlkLE_(v)E_(vi) E_(a) 313 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E_(a) 314 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E_(a) 315 E_(1a)E₅E_(i)E₄ AlkLE_(v)E_(vi) E_(a) 316 E_(1b)E₅E_(i)E₄ AlkLE_(v)E_(vi) E_(a) 317 E_(1a)E₅E_(ii)E₄ AlkLE_(v)E_(vi) E_(a) 318 E_(1b)E₅E_(ii)E₄ AlkLE_(v)E_(vi) E_(a) 319 E_(1a)E₅E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E_(a) 320 E_(1b)E₅E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E_(a) 321 E_(1a)E_(iii) AlkLE_(v)E_(vi) E_(a) 322 E_(1b)E_(iii) AlkLE_(v)E_(vi) E_(a) 323 E_(1a)E₅E_(iii) AlkLE_(v)E_(vi) E_(a) 324 E_(1b)E₅E_(iii) AlkLE_(v)E_(vi) E_(a) 325 E_(1a)E_(iii)E₄ AlkLE_(v)E_(vi) E_(a) 326 E_(1b)E_(iii)E₄ AlkLE_(v)E_(vi) E_(a) 327 E_(1a)E₅E_(iii)E₄ AlkLE_(v)E_(vi) E_(a) 328 E_(1b)E₅E_(iii)E₄ AlkLE_(v)E_(vi) E_(a) 329 E_(1a)E_(iv) AlkLE_(v)E_(vi) E_(a) 330 E_(1b)E_(iv) AlkLE_(v)E_(vi) E_(a) 331 E_(1a)E₅E_(iv) AlkLE_(v)E_(vi) E_(a) 332 E_(1b)E₅E_(iv) AlkLE_(v)E_(vi) E_(a) 333 E_(1a)E_(iv)E₄ AlkLE_(v)E_(vi) E_(a) 334 E_(1b)E_(iv)E₄ AlkLE_(v)E_(vi) E_(a) 335 E_(1a)E₅E_(iv)E₄ AlkLE_(v)E_(vi) E_(a) 336 E_(1b)E₅E_(iv)E₄ AlkLE_(v)E_(vi) E_(a) 337 E_(1a) AlkLE_(v)E_(vi) E₄* E_(a) 338 E_(1b) AlkLE_(v)E_(vi) E₄* E_(a) 339 E_(1a)E₅ AlkLE_(v)E_(vi) E₄* E_(a) 340 E_(1b)E₅ AlkLE_(v)E_(vi) E₄* E_(a) 341 E_(1a)E_(i) AlkLE_(v)E_(vi) E₄* E_(a) 342 E_(1b)E_(i) AlkLE_(v)E_(vi) E₄* E_(a) 343 E_(1a)E_(ii) AlkLE_(v)E_(vi) E₄* E_(a) 344 E_(1b)E_(ii) AlkLE_(v)E_(vi) E₄* E_(a) 345 E_(1a)E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* E_(a) 346 E_(1b)E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* E_(a) 347 E_(1a)E₅E_(i) AlkLE_(v)E_(vi) E₄* E_(a) 348 E_(1b)E₅E_(i) AlkLE_(v)E_(vi) E₄* E_(a) 349 E_(1a)E₅E_(ii) AlkLE_(v)E_(vi) E₄* E_(a) 350 E_(1b)E₅E_(ii) AlkLE_(v)E_(vi) E₄* E_(a) 351 E_(1a)E₅E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* E_(a) 352 E_(1b)E₅E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* E_(a) 353 E_(1a)E₄ AlkLE_(v)E_(vi) E₄* E_(a) 354 E_(1b)E₄ AlkLE_(v)E_(vi) E₄* E_(a) 355 E_(1a)E₅E₄ AlkLE_(v)E_(vi) E₄* E_(a) 356 E_(1b)E₅E₄ AlkLE_(v)E_(vi) E₄* E_(a) 357 E_(1a)E_(i)E₄ AlkLE_(v)E_(vi) E₄* E_(a) 358 E_(1b)E_(i)E₄ AlkLE_(v)E_(vi) E₄* E_(a) 359 E_(1a)E_(ii)E₄ AlkLE_(v)E_(vi) E₄* E_(a) 360 E_(1b)E_(ii)E₄ AlkLE_(v)E_(vi) E₄* E_(a) 361 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* E_(a) 362 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* E_(a) 363 E_(1a)E₅E_(i)E₄ AlkLE_(v)E_(vi) E₄* E_(a) 364 E_(1b)E₅E_(i)E₄ AlkLE_(v)E_(vi) E₄* E_(a) 365 E_(1a)E₅E_(ii)E₄ AlkLE_(v)E_(vi) E₄* E_(a) 366 E_(1b)E₅E_(ii)E₄ AlkLE_(v)E_(vi) E₄* E_(a) 367 E_(1a)E₅E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* E_(a) 368 E_(1b)E₅E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* E_(a) 369 E_(1a)E_(iii) AlkLE_(v)E_(vi) E₄* E_(a) 370 E_(1b)E_(iii) AlkLE_(v)E_(vi) E₄* E_(a) 371 E_(1a)E₅E_(iii) AlkLE_(v)E_(vi) E₄* E_(a) 372 E_(1b)E₅E_(iii) AlkLE_(v)E_(vi) E₄* E_(a) 373 E_(1a)E_(iii)E₄ AlkLE_(v)E_(vi) E₄* E_(a) 374 E_(1b)E_(iii)E₄ AlkLE_(v)E_(vi) E₄* E_(a) 375 E_(1a)E₅E_(iii)E₄ AlkLE_(v)E_(vi) E₄* E_(a) 376 E_(1b)E₅E_(iii)E₄ AlkLE_(v)E_(vi) E₄* E_(a) 377 E_(1a)E_(iv) AlkLE_(v)E_(vi) E₄* E_(a) 378 E_(1b)E_(iv) AlkLE_(v)E_(vi) E₄* E_(a) 379 E_(1a)E₅E_(iv) AlkLE_(v)E_(vi) E₄* E_(a) 380 E_(1b)E₅E_(iv) AlkLE_(v)E_(vi) E₄* E_(a) 381 E_(1a)E_(iv)E₄ AlkLE_(v)E_(vi) E₄* E_(a) 382 E_(1b)E_(iv)E₄ AlkLE_(v)E_(vi) E₄* E_(a) 383 E_(1a)E₅E_(iv)E₄ AlkLE_(v)E_(vi) E₄* E_(a) 384 E_(1b)E₅E_(iv)E₄ AlkLE_(v)E_(vi) E₄* E_(a) 385 E_(1a) E_(v)E_(vi) E_(b) 386 E_(1b) E_(v)E_(vi) E_(b) 387 E_(1a)E₅ E_(v)E_(vi) E_(b) 388 E_(1b)E₅ E_(v)E_(vi) E_(b) 389 E_(1a)E_(i) E_(v)E_(vi) E_(b) 390 E_(1b)E_(i) E_(v)E_(vi) E_(b) 391 E_(1a)E_(ii) E_(v)E_(vi) E_(b) 392 E_(1b)E_(ii) E_(v)E_(vi) E_(b) 393 E_(1a)E_(ii)E_(iib) E_(v)E_(vi) E_(b) 394 E_(1b)E_(ii)E_(iib) E_(v)E_(vi) E_(b) 395 E_(1a)E₅E_(i) E_(v)E_(vi) E_(b) 396 E_(1b)E₅E_(i) E_(v)E_(vi) E_(b) 397 E_(1a)E₅E_(ii) E_(v)E_(vi) E_(b) 398 E_(1b)E₅E_(ii) E_(v)E_(vi) E_(b) 399 E_(1a)E₅E_(ii)E_(iib) E_(v)E_(vi) E_(b) 400 E_(1b)E₅E_(ii)E_(iib) E_(v)E_(vi) E_(b) 401 E_(1a)E₄ E_(v)E_(vi) E_(b) 402 E_(1b)E₄ E_(v)E_(vi) E_(b) 403 E_(1a)E₅E₄ E_(v)E_(vi) E_(b) 404 E_(1b)E₅E₄ E_(v)E_(vi) E_(b) 405 E_(1a)E_(i)E₄ E_(v)E_(vi) E_(b) 406 E_(1b)E_(i)E₄ E_(v)E_(vi) E_(b) 407 E_(1a)E_(ii)E₄ E_(v)E_(vi) E_(b) 408 E_(1b)E_(ii)E₄ E_(v)E_(vi) E_(b) 409 E_(1a)E_(ii)E_(iib)E₄ E_(v)E_(vi) E_(b) 410 E_(1b)E_(ii)E_(iib)E₄ E_(v)E_(vi) E_(b) 411 E_(1a)E₅E_(i)E₄ E_(v)E_(vi) E_(b) 412 E_(1b)E₅E_(i)E₄ E_(v)E_(vi) E_(b) 413 E_(1a)E₅E_(ii)E₄ E_(v)E_(vi) E_(b) 414 E_(1b)E₅E_(ii)E₄ E_(v)E_(vi) E_(b) 415 E_(1a)E₅E_(ii)E_(iib)E₄ E_(v)E_(vi) E_(b) 416 E_(1b)E₅E_(ii)E_(iib)E₄ E_(v)E_(vi) E_(b) 417 E_(1a)E_(iii) E_(v)E_(vi) E_(b) 418 E_(1b)E_(iii) E_(v)E_(vi) E_(b) 419 E_(1a)E₅E_(iii) E_(v)E_(vi) E_(b) 420 E_(1b)E₅E_(iii) E_(v)E_(vi) E_(b) 421 E_(1a)E_(iii)E₄ E_(v)E_(vi) E_(b) 422 E_(1b)E_(iii)E₄ E_(v)E_(vi) E_(b) 423 E_(1a)E₅E_(iii)E₄ E_(v)E_(vi) E_(b) 424 E_(1b)E₅E_(iii)E₄ E_(v)E_(vi) E_(b) 425 E_(1a)E_(iv) E_(v)E_(vi) E_(b) 426 E_(1b)E_(iv) E_(v)E_(vi) E_(b) 427 E_(1a)E₅E_(iv) E_(v)E_(vi) E_(b) 428 E_(1b)E₅E_(iv) E_(v)E_(vi) E_(b) 429 E_(1a)E_(iv)E₄ E_(v)E_(vi) E_(b) 430 E_(1b)E_(iv)E₄ E_(v)E_(vi) E_(b) 431 E_(1a)E₅E_(iv)E₄ E_(v)E_(vi) E_(b) 432 E_(1b)E₅E_(iv)E₄ E_(v)E_(vi) E_(b) 433 E_(1a) E_(v)E_(vi) E₄* E_(b) 434 E_(1b) E_(v)E_(vi) E₄* E_(b) 435 E_(1a)E₅ E_(v)E_(vi) E₄* E_(b) 436 E_(1b)E₅ E_(v)E_(vi) E₄* E_(b) 437 E_(1a)E_(i) E_(v)E_(vi) E₄* E_(b) 438 E_(1b)E_(i) E_(v)E_(vi) E₄* E_(b) 439 E_(1a)E_(ii) E_(v)E_(vi) E₄* E_(b) 440 E_(1b)E_(ii) E_(v)E_(vi) E₄* E_(b) 441 E_(1a)E_(ii)E_(iib) E_(v)E_(vi) E₄* E_(b) 442 E_(1b)E_(ii)E_(iib) E_(v)E_(vi) E₄* E_(b) 443 E_(1a)E₅E_(i) E_(v)E_(vi) E₄* E_(b) 444 E_(1b)E₅E_(i) E_(v)E_(vi) E₄* E_(b) 445 E_(1a)E₅E_(ii) E_(v)E_(vi) E₄* E_(b) 446 E_(1b)E₅E_(ii) E_(v)E_(vi) E₄* E_(b) 447 E_(1a)E₅E_(ii)E_(iib) E_(v)E_(vi) E₄* E_(b) 448 E_(1b)E₅E_(ii)E_(iib) E_(v)E_(vi) E₄* E_(b) 449 E_(1a)E₄ E_(v)E_(vi) E₄* E_(b) 450 E_(1b)E₄ E_(v)E_(vi) E₄* E_(b) 451 E_(1a)E₅E₄ E_(v)E_(vi) E₄* E_(b) 452 E_(1b)E₅E₄ E_(v)E_(vi) E₄* E_(b) 453 E_(1a)E_(i)E₄ E_(v)E_(vi) E₄* E_(b) 454 E_(1b)E_(i)E₄ E_(v)E_(vi) E₄* E_(b) 455 E_(1a)E_(ii)E₄ E_(v)E_(vi) E₄* E_(b) 456 E_(1b)E_(ii)E₄ E_(v)E_(vi) E₄* E_(b) 457 E_(1a)E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* E_(b) 458 E_(1b)E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* E_(b) 459 E_(1a)E₅E_(i)E₄ E_(v)E_(vi) E₄* E_(b) 460 E_(1b)E₅E_(i)E₄ E_(v)E_(vi) E₄* E_(b) 461 E_(1a)E₅E_(ii)E₄ E_(v)E_(vi) E₄* E_(b) 462 E_(1b)E₅E_(ii)E₄ E_(v)E_(vi) E₄* E_(b) 463 E_(1a)E₅E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* E_(b) 464 E_(1b)E₅E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* E_(b) 465 E_(1a)E_(iii) E_(v)E_(vi) E₄* E_(b) 466 E_(1b)E_(iii) E_(v)E_(vi) E₄* E_(b) 467 E_(1a)E₅E_(iii) E_(v)E_(vi) E₄* E_(b) 468 E_(1b)E₅E_(iii) E_(v)E_(vi) E₄* E_(b) 469 E_(1a)E_(iii)E₄ E_(v)E_(vi) E₄* E_(b) 470 E_(1b)E_(iii)E₄ E_(v)E_(vi) E₄* E_(b) 471 E_(1a)E₅E_(iii)E₄ E_(v)E_(vi) E₄* E_(b) 472 E_(1b)E₅E_(iii)E₄ E_(v)E_(vi) E₄* E_(b) 473 E_(1a)E_(iv) E_(v)E_(vi) E₄* E_(b) 474 E_(1b)E_(iv) E_(v)E_(vi) E₄* E_(b) 475 E_(1a)E₅E_(iv) E_(v)E_(vi) E₄* E_(b) 476 E_(1b)E₅E_(iv) E_(v)E_(vi) E₄* E_(b) 477 E_(1a)E_(iv)E₄ E_(v)E_(vi) E₄* E_(b) 478 E_(1b)E_(iv)E₄ E_(v)E_(vi) E₄* E_(b) 479 E_(1a)E₅E_(iv)E₄ E_(v)E_(vi) E₄* E_(b) 480 E_(1b)E₅E_(iv)E₄ E_(v)E_(vi) E₄* E_(b) 481 E_(1a) AlkLE_(v)E_(vi) E_(b) 482 E_(1b) AlkLE_(v)E_(vi) E_(b) 483 E_(1a)E₅ AlkLE_(v)E_(vi) E_(b) 484 E_(1b)E₅ AlkLE_(v)E_(vi) E_(b) 485 E_(1a)E_(i) AlkLE_(v)E_(vi) E_(b) 486 E_(1b)E_(i) AlkLE_(v)E_(vi) E_(b) 487 E_(1a)E_(ii) AlkLE_(v)E_(vi) E_(b) 488 E_(1b)E_(ii) AlkLE_(v)E_(vi) E_(b) 489 E_(1a)E_(ii)E_(iib) AlkLE_(v)E_(vi) E_(b) 490 E_(1b)E_(ii)E_(iib) AlkLE_(v)E_(vi) E_(b) 491 E_(1a)E₅E_(i) AlkLE_(v)E_(vi) E_(b) 492 E_(1b)E₅E_(i) AlkLE_(v)E_(vi) E_(b) 493 E_(1a)E₅E_(ii) AlkLE_(v)E_(vi) E_(b) 494 E_(1b)E₅E_(ii) AlkLE_(v)E_(vi) E_(b) 495 E_(1a)E₅E_(ii)E_(iib) AlkLE_(v)E_(vi) E_(b) 496 E_(1b)E₅E_(ii)E_(iib) AlkLE_(v)E_(vi) E_(b) 497 E_(1a)E₄ AlkLE_(v)E_(vi) E_(b) 498 E_(1b)E₄ AlkLE_(v)E_(vi) E_(b) 499 E_(1a)E₅E₄ AlkLE_(v)E_(vi) E_(b) 500 E_(1b)E₅E₄ AlkLE_(v)E_(vi) E_(b) 501 E_(1a)E_(i)E₄ AlkLE_(v)E_(vi) E_(b) 502 E_(1b)E_(i)E₄ AlkLE_(v)E_(vi) E_(b) 503 E_(1a)E_(ii)E₄ AlkLE_(v)E_(vi) E_(b) 504 E_(1b)E_(ii)E₄ AlkLE_(v)E_(vi) E_(b) 505 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E_(b) 506 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E_(b) 507 E_(1a)E₅E_(i)E₄ AlkLE_(v)E_(vi) E_(b) 508 E_(1b)E₅E_(i)E₄ AlkLE_(v)E_(vi) E_(b) 509 E_(1a)E₅E_(ii)E₄ AlkLE_(v)E_(vi) E_(b) 510 E_(1b)E₅E_(ii)E₄ AlkLE_(v)E_(vi) E_(b) 511 E_(1a)E₅E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E_(b) 512 E_(1b)E₅E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E_(b) 513 E_(1a)E_(iii) AlkLE_(v)E_(vi) E_(b) 514 E_(1b)E_(iii) AlkLE_(v)E_(vi) E_(b) 515 E_(1a)E₅E_(iii) AlkLE_(v)E_(vi) E_(b) 516 E_(1b)E₅E_(iii) AlkLE_(v)E_(vi) E_(b) 517 E_(1a)E_(iii)E₄ AlkLE_(v)E_(vi) E_(b) 518 E_(1b)E_(iii)E₄ AlkLE_(v)E_(vi) E_(b) 519 E_(1a)E₅E_(iii)E₄ AlkLE_(v)E_(vi) E_(b) 520 E_(1b)E₅E_(iii)E₄ AlkLE_(v)E_(vi) E_(b) 521 E_(1a)E_(iv) AlkLE_(v)E_(vi) E_(b) 522 E_(1b)E_(iv) AlkLE_(v)E_(vi) E_(b) 523 E_(1a)E₅E_(iv) AlkLE_(v)E_(vi) E_(b) 524 E_(1b)E₅E_(iv) AlkLE_(v)E_(vi) E_(b) 525 E_(1a)E_(iv)E₄ AlkLE_(v)E_(vi) E_(b) 526 E_(1b)E_(iv)E₄ AlkLE_(v)E_(vi) E_(b) 527 E_(1a)E₅E_(iv)E₄ AlkLE_(v)E_(vi) E_(b) 528 E_(1b)E₅E_(iv)E₄ AlkLE_(v)E_(vi) E_(b) 529 E_(1a) AlkLE_(v)E_(vi) E₄* E_(b) 530 E_(1b) AlkLE_(v)E_(vi) E₄* E_(b) 531 E_(1a)E₅ AlkLE_(v)E_(vi) E₄* E_(b) 532 E_(1b)E₅ AlkLE_(v)E_(vi) E₄* E_(b) 533 E_(1a)E_(i) AlkLE_(v)E_(vi) E₄* E_(b) 534 E_(1b)E_(i) AlkLE_(v)E_(vi) E₄* E_(b) 535 E_(1a)E_(ii) AlkLE_(v)E_(vi) E₄* E_(b) 536 E_(1b)E_(ii) AlkLE_(v)E_(vi) E₄* E_(b) 537 E_(1a)E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* E_(b) 538 E_(1b)E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* E_(b) 539 E_(1a)E₅E_(i) AlkLE_(v)E_(vi) E₄* E_(b) 540 E_(1b)E₅E_(i) AlkLE_(v)E_(vi) E₄* E_(b) 541 E_(1a)E₅E_(ii) AlkLE_(v)E_(vi) E₄* E_(b) 542 E_(1b)E₅E_(ii) AlkLE_(v)E_(vi) E₄* E_(b) 543 E_(1a)E₅E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* E_(b) 544 E_(1b)E₅E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* E_(b) 545 E_(1a)E₄ AlkLE_(v)E_(vi) E₄* E_(b) 546 E_(1b)E₄ AlkLE_(v)E_(vi) E₄* E_(b) 547 E_(1a)E₅E₄ AlkLE_(v)E_(vi) E₄* E_(b) 548 E_(1b)E₅E₄ AlkLE_(v)E_(vi) E₄* E_(b) 549 E_(1a)E_(i)E₄ AlkLE_(v)E_(vi) E₄* E_(b) 550 E_(1b)E_(i)E₄ AlkLE_(v)E_(vi) E₄* E_(b) 551 E_(1a)E_(ii)E₄ AlkLE_(v)E_(vi) E₄* E_(b) 552 E_(1b)E_(ii)E₄ AlkLE_(v)E_(vi) E₄* E_(b) 553 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* E_(b) 554 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* E_(b) 555 E_(1a)E₅E_(i)E₄ AlkLE_(v)E_(vi) E₄* E_(b) 556 E_(1b)E₅E_(i)E₄ AlkLE_(v)E_(vi) E₄* E_(b) 557 E_(1a)E₅E_(ii)E₄ AlkLE_(v)E_(vi) E₄* E_(b) 558 E_(1b)E₅E_(ii)E₄ AlkLE_(v)E_(vi) E₄* E_(b) 559 E_(1a)E₅E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* E_(b) 560 E_(1b)E₅E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* E_(b) 561 E_(1a)E_(iii) AlkLE_(v)E_(vi) E₄* E_(b) 562 E_(1b)E_(iii) AlkLE_(v)E_(vi) E₄* E_(b) 563 E_(1a)E₅E_(iii) AlkLE_(v)E_(vi) E₄* E_(b) 564 E_(1b)E₅E_(iii) AlkLE_(v)E_(vi) E₄* E_(b) 565 E_(1a)E_(iii)E₄ AlkLE_(v)E_(vi) E₄* E_(b) 566 E_(1b)E_(iii)E₄ AlkLE_(v)E_(vi) E₄* E_(b) 567 E_(1a)E₅E_(iii)E₄ AlkLE_(v)E_(vi) E₄* E_(b) 568 E_(1b)E₅E_(iii)E₄ AlkLE_(v)E_(vi) E₄* E_(b) 569 E_(1a)E_(iv) AlkLE_(v)E_(vi) E₄* E_(b) 570 E_(1b)E_(iv) AlkLE_(v)E_(vi) E₄* E_(b) 571 E_(1a)E₅E_(iv) AlkLE_(v)E_(vi) E₄* E_(b) 572 E_(1b)E₅E_(iv) AlkLE_(v)E_(vi) E₄* E_(b) 573 E_(1a)E_(iv)E₄ AlkLE_(v)E_(vi) E₄* E_(b) 574 E_(1b)E_(iv)E₄ AlkLE_(v)E_(vi) E₄* E_(b) 575 E_(1a)E₅E_(iv)E₄ AlkLE_(v)E_(vi) E₄* E_(b) 576 E_(1b)E₅E_(iv)E₄ AlkLE_(v)E_(vi) E₄* E_(b) 577 E_(1a) E_(v)E_(vi) E_(d) 578 E_(1b) E_(v)E_(vi) E_(d) 579 E_(1a)E₅ E_(v)E_(vi) E_(d) 580 E_(1b)E₅ E_(v)E_(vi) E_(d) 581 E_(1a)E_(i) E_(v)E_(vi) E_(d) 582 E_(1b)E_(i) E_(v)E_(vi) E_(d) 583 E_(1a)E_(ii) E_(v)E_(vi) E_(d) 584 E_(1b)E_(ii) E_(v)E_(vi) E_(d) 585 E_(1a)E_(ii)E_(iib) E_(v)E_(vi) E_(d) 586 E_(1b)E_(ii)E_(iib) E_(v)E_(vi) E_(d) 587 E_(1a)E₅E_(i) E_(v)E_(vi) E_(d) 588 E_(1b)E₅E_(i) E_(v)E_(vi) E_(d) 589 E_(1a)E₅E_(ii) E_(v)E_(vi) E_(d) 590 E_(1b)E₅E_(ii) E_(v)E_(vi) E_(d) 591 E_(1a)E₅E_(ii)E_(iib) E_(v)E_(vi) E_(d) 592 E_(1b)E₅E_(ii)E_(iib) E_(v)E_(vi) E_(d) 593 E_(1a)E₄ E_(v)E_(vi) E_(d) 594 E_(1b)E₄ E_(v)E_(vi) E_(d) 595 E_(1a)E₅E₄ E_(v)E_(vi) E_(d) 596 E_(1b)E₅E₄ E_(v)E_(vi) E_(d) 597 E_(1a)E_(i)E₄ E_(v)E_(vi) E_(d) 598 E_(1b)E_(i)E₄ E_(v)E_(vi) E_(d) 599 E_(1a)E_(ii)E₄ E_(v)E_(vi) E_(d) 600 E_(1b)E_(ii)E₄ E_(v)E_(vi) E_(d) 601 E_(1a)E_(ii)E_(iib)E₄ E_(v)E_(vi) E_(d) 602 E_(1b)E_(ii)E_(iib)E₄ E_(v)E_(vi) E_(d) 603 E_(1a)E₅E_(i)E₄ E_(v)E_(vi) E_(d) 604 E_(1b)E₅E_(i)E₄ E_(v)E_(vi) E_(d) 605 E_(1a)E₅E_(ii)E₄ E_(v)E_(vi) E_(d) 606 E_(1b)E₅E_(ii)E₄ E_(v)E_(vi) E_(d) 607 E_(1a)E₅E_(ii)E_(iib)E₄ E_(v)E_(vi) E_(d) 608 E_(1b)E₅E_(ii)E_(iib)E₄ E_(v)E_(vi) E_(d) 609 E_(1a)E_(iii) E_(v)E_(vi) E_(d) 610 E_(1b)E_(iii) E_(v)E_(vi) E_(d) 611 E_(1a)E₅E_(iii) E_(v)E_(vi) E_(d) 612 E_(1b)E₅E_(iii) E_(v)E_(vi) E_(d) 613 E_(1a)E_(iii)E₄ E_(v)E_(vi) E_(d) 614 E_(1b)E_(iii)E₄ E_(v)E_(vi) E_(d) 615 E_(1a)E₅E_(iii)E₄ E_(v)E_(vi) E_(d) 616 E_(1b)E₅E_(iii)E₄ E_(v)E_(vi) E_(d) 617 E_(1a)E_(iv) E_(v)E_(vi) E_(d) 618 E_(1b)E_(iv) E_(v)E_(vi) E_(d) 619 E_(1a)E₅E_(iv) E_(v)E_(vi) E_(d) 620 E_(1b)E₅E_(iv) E_(v)E_(vi) E_(d) 621 E_(1a)E_(iv)E₄ E_(v)E_(vi) E_(d) 622 E_(1b)E_(iv)E₄ E_(v)E_(vi) E_(d) 623 E_(1a)E₅E_(iv)E₄ E_(v)E_(vi) E_(d) 624 E_(1b)E₅E_(iv)E₄ E_(v)E_(vi) E_(d) 625 E_(1a) E_(v)E_(vi) E₄* E_(d) 626 E_(1b) E_(v)E_(vi) E₄* E_(d) 627 E_(1a)E₅ E_(v)E_(vi) E₄* E_(d) 628 E_(1b)E₅ E_(v)E_(vi) E₄* E_(d) 629 E_(1a)E_(i) E_(v)E_(vi) E₄* E_(d) 630 E_(1b)E_(i) E_(v)E_(vi) E₄* E_(d) 631 E_(1a)E_(ii) E_(v)E_(vi) E₄* E_(d) 632 E_(1b)E_(ii) E_(v)E_(vi) E₄* E_(d) 633 E_(1a)E_(ii)E_(iib) E_(v)E_(vi) E₄* E_(d) 634 E_(1b)E_(ii)E_(iib) E_(v)E_(vi) E₄* E_(d) 635 E_(1a)E₅E_(i) E_(v)E_(vi) E₄* E_(d) 636 E_(1b)E₅E_(i) E_(v)E_(vi) E₄* E_(d) 637 E_(1a)E₅E_(ii) E_(v)E_(vi) E₄* E_(d) 638 E_(1b)E₅E_(ii) E_(v)E_(vi) E₄* E_(d) 639 E_(1a)E₅E_(ii)E_(iib) E_(v)E_(vi) E₄* E_(d) 640 E_(1b)E₅E_(ii)E_(iib) E_(v)E_(vi) E₄* E_(d) 641 E_(1a)E₄ E_(v)E_(vi) E₄* E_(d) 642 E_(1b)E₄ E_(v)E_(vi) E₄* E_(d) 643 E_(1a)E₅E₄ E_(v)E_(vi) E₄* E_(d) 644 E_(1b)E₅E₄ E_(v)E_(vi) E₄* E_(d) 645 E_(1a)E_(i)E₄ E_(v)E_(vi) E₄* E_(d) 646 E_(1b)E_(i)E₄ E_(v)E_(vi) E₄* E_(d) 647 E_(1a)E_(ii)E₄ E_(v)E_(vi) E₄* E_(d) 648 E_(1b)E_(ii)E₄ E_(v)E_(vi) E₄* E_(d) 649 E_(1a)E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* E_(d) 650 E_(1b)E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* E_(d) 651 E_(1a)E₅E_(i)E₄ E_(v)E_(vi) E₄* E_(d) 652 E_(1b)E₅E_(i)E₄ E_(v)E_(vi) E₄* E_(d) 653 E_(1a)E₅E_(ii)E₄ E_(v)E_(vi) E₄* E_(d) 654 E_(1b)E₅E_(ii)E₄ E_(v)E_(vi) E₄* E_(d) 655 E_(1a)E₅E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* E_(d) 656 E_(1b)E₅E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* E_(d) 657 E_(1a)E_(iii) E_(v)E_(vi) E₄* E_(d) 658 E_(1b)E_(iii) E_(v)E_(vi) E₄* E_(d) 659 E_(1a)E₅E_(iii) E_(v)E_(vi) E₄* E_(d) 660 E_(1b)E₅E_(iii) E_(v)E_(vi) E₄* E_(d) 661 E_(1a)E_(iii)E₄ E_(v)E_(vi) E₄* E_(d) 662 E_(1b)E_(iii)E₄ E_(v)E_(vi) E₄* E_(d) 663 E_(1a)E₅E_(iii)E₄ E_(v)E_(vi) E₄* E_(d) 664 E_(1b)E₅E_(iii)E₄ E_(v)E_(vi) E₄* E_(d) 665 E_(1a)E_(iv) E_(v)E_(vi) E₄* E_(d) 666 E_(1b)E_(iv) E_(v)E_(vi) E₄* E_(d) 667 E_(1a)E₅E_(iv) E_(v)E_(vi) E₄* E_(d) 668 E_(1b)E₅E_(iv) E_(v)E_(vi) E₄* E_(d) 669 E_(1a)E_(iv)E₄ E_(v)E_(vi) E₄* E_(d) 670 E_(1b)E_(iv)E₄ E_(v)E_(vi) E₄* E_(d) 671 E_(1a)E₅E_(iv)E₄ E_(v)E_(vi) E₄* E_(d) 672 E_(1b)E₅E_(iv)E₄ E_(v)E_(vi) E₄* E_(d) 673 E_(1a) AlkLE_(v)E_(vi) E_(d) 674 E_(1b) AlkLE_(v)E_(vi) E_(d) 675 E_(1a)E₅ AlkLE_(v)E_(vi) E_(d) 676 E_(1b)E₅ AlkLE_(v)E_(vi) E_(d) 677 E_(1a)E_(i) AlkLE_(v)E_(vi) E_(d) 678 E_(1b)E_(i) AlkLE_(v)E_(vi) E_(d) 679 E_(1a)E_(ii) AlkLE_(v)E_(vi) E_(d) 680 E_(1b)E_(ii) AlkLE_(v)E_(vi) E_(d) 681 E_(1a)E_(ii)E_(iib) AlkLE_(v)E_(vi) E_(d) 682 E_(1b)E_(ii)E_(iib) AlkLE_(v)E_(vi) E_(d) 683 E_(1a)E₅E_(i) AlkLE_(v)E_(vi) E_(d) 684 E_(1b)E₅E_(i) AlkLE_(v)E_(vi) E_(d) 685 E_(1a)E₅E_(ii) AlkLE_(v)E_(vi) E_(d) 686 E_(1b)E₅E_(ii) AlkLE_(v)E_(vi) E_(d) 687 E_(1a)E₅E_(ii)E_(iib) AlkLE_(v)E_(vi) E_(d) 688 E_(1b)E₅E_(ii)E_(iib) AlkLE_(v)E_(vi) E_(d) 689 E_(1a)E₄ AlkLE_(v)E_(vi) E_(d) 690 E_(1b)E₄ AlkLE_(v)E_(vi) E_(d) 691 E_(1a)E₅E₄ AlkLE_(v)E_(vi) E_(d) 692 E_(1b)E₅E₄ AlkLE_(v)E_(vi) E_(d) 693 E_(1a)E_(i)E₄ AlkLE_(v)E_(vi) E_(d) 694 E_(1b)E_(i)E₄ AlkLE_(v)E_(vi) E_(d) 695 E_(1a)E_(ii)E₄ AlkLE_(v)E_(vi) E_(d) 696 E_(1b)E_(ii)E₄ AlkLE_(v)E_(vi) E_(d) 697 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E_(d) 698 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E_(d) 699 E_(1a)E₅E_(i)E₄ AlkLE_(v)E_(vi) E_(d) 700 E_(1b)E₅E_(i)E₄ AlkLE_(v)E_(vi) E_(d) 701 E_(1a)E₅E_(ii)E₄ AlkLE_(v)E_(vi) E_(d) 702 E_(1b)E₅E_(ii)E₄ AlkLE_(v)E_(vi) E_(d) 703 E_(1a)E₅E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E_(d) 704 E_(1b)E₅E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E_(d) 705 E_(1a)E_(iii) AlkLE_(v)E_(vi) E_(d) 706 E_(1b)E_(iii) AlkLE_(v)E_(vi) E_(d) 707 E_(1a)E₅E_(iii) AlkLE_(v)E_(vi) E_(d) 708 E_(1b)E₅E_(iii) AlkLE_(v)E_(vi) E_(d) 709 E_(1a)E_(iii)E₄ AlkLE_(v)E_(vi) E_(d) 710 E_(1b)E_(iii)E₄ AlkLE_(v)E_(vi) E_(d) 711 E_(1a)E₅E_(iii)E₄ AlkLE_(v)E_(vi) E_(d) 712 E_(1b)E₅E_(iii)E₄ AlkLE_(v)E_(vi) E_(d) 713 E_(1a)E_(iv) AlkLE_(v)E_(vi) E_(d) 714 E_(1b)E_(iv) AlkLE_(v)E_(vi) E_(d) 715 E_(1a)E₅E_(iv) AlkLE_(v)E_(vi) E_(d) 716 E_(1b)E₅E_(iv) AlkLE_(v)E_(vi) E_(d) 717 E_(1a)E_(iv)E₄ AlkLE_(v)E_(vi) E_(d) 718 E_(1b)E_(iv)E₄ AlkLE_(v)E_(vi) E_(d) 719 E_(1a)E₅E_(iv)E₄ AlkLE_(v)E_(vi) E_(d) 720 E_(1b)E₅E_(iv)E₄ AlkLE_(v)E_(vi) E_(d) 721 E_(1a) AlkLE_(v)E_(vi) E₄* E_(d) 722 E_(1b) AlkLE_(v)E_(vi) E₄* E_(d) 723 E_(1a)E₅ AlkLE_(v)E_(vi) E₄* E_(d) 724 E_(1b)E₅ AlkLE_(v)E_(vi) E₄* E_(d) 725 E_(1a)E_(i) AlkLE_(v)E_(vi) E₄* E_(d) 726 E_(1b)E_(i) AlkLE_(v)E_(vi) E₄* E_(d) 727 E_(1a)E_(ii) AlkLE_(v)E_(vi) E₄* E_(d) 728 E_(1b)E_(ii) AlkLE_(v)E_(vi) E₄* E_(d) 729 E_(1a)E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* E_(d) 730 E_(1b)E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* E_(d) 731 E_(1a)E₅E_(i) AlkLE_(v)E_(vi) E₄* E_(d) 732 E_(1b)E₅E_(i) AlkLE_(v)E_(vi) E₄* E_(d) 733 E_(1a)E₅E_(ii) AlkLE_(v)E_(vi) E₄* E_(d) 734 E_(1b)E₅E_(ii) AlkLE_(v)E_(vi) E₄* E_(d) 735 E_(1a)E₅E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* E_(d) 736 E_(1b)E₅E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* E_(d) 737 E_(1a)E₄ AlkLE_(v)E_(vi) E₄* E_(d) 738 E_(1b)E₄ AlkLE_(v)E_(vi) E₄* E_(d) 739 E_(1a)E₅E₄ AlkLE_(v)E_(vi) E₄* E_(d) 740 E_(1b)E₅E₄ AlkLE_(v)E_(vi) E₄* E_(d) 741 E_(1a)E_(i)E₄ AlkLE_(v)E_(vi) E₄* E_(d) 742 E_(1b)E_(i)E₄ AlkLE_(v)E_(vi) E₄* E_(d) 743 E_(1a)E_(ii)E₄ AlkLE_(v)E_(vi) E₄* E_(d) 744 E_(1b)E_(ii)E₄ AlkLE_(v)E_(vi) E₄* E_(d) 745 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* E_(d) 746 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* E_(d) 747 E_(1a)E₅E_(i)E₄ AlkLE_(v)E_(vi) E₄* E_(d) 748 E_(1b)E₅E_(i)E₄ AlkLE_(v)E_(vi) E₄* E_(d) 749 E_(1a)E₅E_(ii)E₄ AlkLE_(v)E_(vi) E₄* E_(d) 750 E_(1b)E₅E_(ii)E₄ AlkLE_(v)E_(vi) E₄* E_(d) 751 E_(1a)E₅E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* E_(d) 752 E_(1b)E₅E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* E_(d) 753 E_(1a)E_(iii) AlkLE_(v)E_(vi) E₄* E_(d) 754 E_(1b)E_(iii) AlkLE_(v)E_(vi) E₄* E_(d) 755 E_(1a)E₅E_(iii) AlkLE_(v)E_(vi) E₄* E_(d) 756 E_(1b)E₅E_(iii) AlkLE_(v)E_(vi) E₄* E_(d) 757 E_(1a)E_(iii)E₄ AlkLE_(v)E_(vi) E₄* E_(d) 758 E_(1b)E_(iii)E₄ AlkLE_(v)E_(vi) E₄* E_(d) 759 E_(1a)E₅E_(iii)E₄ AlkLE_(v)E_(vi) E₄* E_(d) 760 E_(1b)E₅E_(iii)E₄ AlkLE_(v)E_(vi) E₄* E_(d) 761 E_(1a)E_(iv) AlkLE_(v)E_(vi) E₄* E_(d) 762 E_(1b)E_(iv) AlkLE_(v)E_(vi) E₄* E_(d) 763 E_(1a)E₅E_(iv) AlkLE_(v)E_(vi) E₄* E_(d) 764 E_(1b)E₅E_(iv) AlkLE_(v)E_(vi) E₄* E_(d) 765 E_(1a)E_(iv)E₄ AlkLE_(v)E_(vi) E₄* E_(d) 766 E_(1b)E_(iv)E₄ AlkLE_(v)E_(vi) E₄* E_(d) 767 E_(1a)E₅E_(iv)E₄ AlkLE_(v)E_(vi) E₄* E_(d) 768 E_(1b)E₅E_(iv)E₄ AlkLE_(v)E_(vi) E₄* E_(d) 769 E_(1a) E_(v)E_(vi) E_(e) 770 E_(1b) E_(v)E_(vi) E_(e) 771 E_(1a)E₅ E_(v)E_(vi) E_(e) 772 E_(1b)E₅ E_(v)E_(vi) E_(e) 773 E_(1a)E_(i) E_(v)E_(vi) E_(e) 774 E_(1b)E_(i) E_(v)E_(vi) E_(e) 775 E_(1a)E_(ii) E_(v)E_(vi) E_(e) 776 E_(1b)E_(ii) E_(v)E_(vi) E_(e) 777 E_(1a)E_(ii)E_(iib) E_(v)E_(vi) E_(e) 778 E_(1b)E_(ii)E_(iib) E_(v)E_(vi) E_(e) 779 E_(1a)E₅E_(i) E_(v)E_(vi) E_(e) 780 E_(1b)E₅E_(i) E_(v)E_(vi) E_(e) 781 E_(1a)E₅E_(ii) E_(v)E_(vi) E_(e) 782 E_(1b)E₅E_(ii) E_(v)E_(vi) E_(e) 783 E_(1a)E₅E_(ii)E_(iib) E_(v)E_(vi) E_(e) 784 E_(1b)E₅E_(ii)E_(iib) E_(v)E_(vi) E_(e) 785 E_(1a)E₄ E_(v)E_(vi) E_(e) 786 E_(1b)E₄ E_(v)E_(vi) E_(e) 787 E_(1a)E₅E₄ E_(v)E_(vi) E_(e) 788 E_(1b)E₅E₄ E_(v)E_(vi) E_(e) 789 E_(1a)E_(i)E₄ E_(v)E_(vi) E_(e) 790 E_(1b)E_(i)E₄ E_(v)E_(vi) E_(e) 791 E_(1a)E_(ii)E₄ E_(v)E_(vi) E_(e) 792 E_(1b)E_(ii)E₄ E_(v)E_(vi) E_(e) 793 E_(1a)E_(ii)E_(iib)E₄ E_(v)E_(vi) E_(e) 794 E_(1b)E_(ii)E_(iib)E₄ E_(v)E_(vi) E_(e) 795 E_(1a)E₅E_(i)E₄ E_(v)E_(vi) E_(e) 796 E_(1b)E₅E_(i)E₄ E_(v)E_(vi) E_(e) 797 E_(1a)E₅E_(ii)E₄ E_(v)E_(vi) E_(e) 798 E_(1b)E₅E_(ii)E₄ E_(v)E_(vi) E_(e) 799 E_(1a)E₅E_(ii)E_(iib)E₄ E_(v)E_(vi) E_(e) 800 E_(1b)E₅E_(ii)E_(iib)E₄ E_(v)E_(vi) E_(e) 801 E_(1a)E_(iii) E_(v)E_(vi) E_(e) 802 E_(1b)E_(iii) E_(v)E_(vi) E_(e) 803 E_(1a)E₅E_(iii) E_(v)E_(vi) E_(e) 804 E_(1b)E₅E_(iii) E_(v)E_(vi) E_(e) 805 E_(1a)E_(iii)E₄ E_(v)E_(vi) E_(e) 806 E_(1b)E_(iii)E₄ E_(v)E_(vi) E_(e) 807 E_(1a)E₅E_(iii)E₄ E_(v)E_(vi) E_(e) 808 E_(1b)E₅E_(iii)E₄ E_(v)E_(vi) E_(e) 809 E_(1a)E_(iv) E_(v)E_(vi) E_(e) 810 E_(1b)E_(iv) E_(v)E_(vi) E_(e) 811 E_(1a)E₅E_(iv) E_(v)E_(vi) E_(e) 812 E_(1b)E₅E_(iv) E_(v)E_(vi) E_(e) 813 E_(1a)E_(iv)E₄ E_(v)E_(vi) E_(e) 814 E_(1b)E_(iv)E₄ E_(v)E_(vi) E_(e) 815 E_(1a)E₅E_(iv)E₄ E_(v)E_(vi) E_(e) 816 E_(1b)E₅E_(iv)E₄ E_(v)E_(vi) E_(e) 817 E_(1a) E_(v)E_(vi) E₄* E_(e) 818 E_(1b) E_(v)E_(vi) E₄* E_(e) 819 E_(1a)E₅ E_(v)E_(vi) E₄* E_(e) 820 E_(1b)E₅ E_(v)E_(vi) E₄* E_(e) 821 E_(1a)E_(i) E_(v)E_(vi) E₄* E_(e) 822 E_(1b)E_(i) E_(v)E_(vi) E₄* E_(e) 823 E_(1a)E_(ii) E_(v)E_(vi) E₄* E_(e) 824 E_(1b)E_(ii) E_(v)E_(vi) E₄* E_(e) 825 E_(1a)E_(ii)E_(iib) E_(v)E_(vi) E₄* E_(e) 826 E_(1b)E_(ii)E_(iib) E_(v)E_(vi) E₄* E_(e) 827 E_(1a)E₅E_(i) E_(v)E_(vi) E₄* E_(e) 828 E_(1b)E₅E_(i) E_(v)E_(vi) E₄* E_(e) 829 E_(1a)E₅E_(ii) E_(v)E_(vi) E₄* E_(e) 830 E_(1b)E₅E_(ii) E_(v)E_(vi) E₄* E_(e) 831 E_(1a)E₅E_(ii)E_(iib) E_(v)E_(vi) E₄* E_(e) 832 E_(1b)E₅E_(ii)E_(iib) E_(v)E_(vi) E₄* E_(e) 833 E_(1a)E₄ E_(v)E_(vi) E₄* E_(e) 834 E_(1b)E₄ E_(v)E_(vi) E₄* E_(e) 835 E_(1a)E₅E₄ E_(v)E_(vi) E₄* E_(e) 836 E_(1b)E₅E₄ E_(v)E_(vi) E₄* E_(e) 837 E_(1a)E_(i)E₄ E_(v)E_(vi) E₄* E_(e) 838 E_(1b)E_(i)E₄ E_(v)E_(vi) E₄* E_(e) 839 E_(1a)E_(ii)E₄ E_(v)E_(vi) E₄* E_(e) 840 E_(1b)E_(ii)E₄ E_(v)E_(vi) E₄* E_(e) 841 E_(1a)E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* E_(e) 842 E_(1b)E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* E_(e) 843 E_(1a)E₅E_(i)E₄ E_(v)E_(vi) E₄* E_(e) 844 E_(1b)E₅E_(i)E₄ E_(v)E_(vi) E₄* E_(e) 845 E_(1a)E₅E_(ii)E₄ E_(v)E_(vi) E₄* E_(e) 846 E_(1b)E₅E_(ii)E₄ E_(v)E_(vi) E₄* E_(e) 847 E_(1a)E₅E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* E_(e) 848 E_(1b)E₅E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* E_(e) 849 E_(1a)E_(iii) E_(v)E_(vi) E₄* E_(e) 850 E_(1b)E_(iii) E_(v)E_(vi) E₄* E_(e) 851 E_(1a)E₅E_(iii) E_(v)E_(vi) E₄* E_(e) 852 E_(1b)E₅E_(iii) E_(v)E_(vi) E₄* E_(e) 853 E_(1a)E_(iii)E₄ E_(v)E_(vi) E₄* E_(e) 854 E_(1b)E_(iii)E₄ E_(v)E_(vi) E₄* E_(e) 855 E_(1a)E₅E_(iii)E₄ E_(v)E_(vi) E₄* E_(e) 856 E_(1b)E₅E_(iii)E₄ E_(v)E_(vi) E₄* E_(e) 857 E_(1a)E_(iv) E_(v)E_(vi) E₄* E_(e) 858 E_(1b)E_(iv) E_(v)E_(vi) E₄* E_(e) 859 E_(1a)E₅E_(iv) E_(v)E_(vi) E₄* E_(e) 860 E_(1b)E₅E_(iv) E_(v)E_(vi) E₄* E_(e) 861 E_(1a)E_(iv)E₄ E_(v)E_(vi) E₄* E_(e) 862 E_(1b)E_(iv)E₄ E_(v)E_(vi) E₄* E_(e) 863 E_(1a)E₅E_(iv)E₄ E_(v)E_(vi) E₄* E_(e) 864 E_(1b)E₅E_(iv)E₄ E_(v)E_(vi) E₄* E_(e) 865 E_(1a) AlkLE_(v)E_(vi) E_(e) 866 E_(1b) AlkLE_(v)E_(vi) E_(e) 867 E_(1a)E₅ AlkLE_(v)E_(vi) E_(e) 868 E_(1b)E₅ AlkLE_(v)E_(vi) E_(e) 869 E_(1a)E_(i) AlkLE_(v)E_(vi) E_(e) 870 E_(1b)E_(i) AlkLE_(v)E_(vi) E_(e) 871 E_(1a)E_(ii) AlkLE_(v)E_(vi) E_(e) 872 E_(1b)E_(ii) AlkLE_(v)E_(vi) E_(e) 873 E_(1a)E_(ii)E_(iib) AlkLE_(v)E_(vi) E_(e) 874 E_(1b)E_(ii)E_(iib) AlkLE_(v)E_(vi) E_(e) 875 E_(1a)E₅E_(i) AlkLE_(v)E_(vi) E_(e) 876 E_(1b)E₅E_(i) AlkLE_(v)E_(vi) E_(e) 877 E_(1a)E₅E_(ii) AlkLE_(v)E_(vi) E_(e) 878 E_(1b)E₅E_(ii) AlkLE_(v)E_(vi) E_(e) 879 E_(1a)E₅E_(ii)E_(iib) AlkLE_(v)E_(vi) E_(e) 880 E_(1b)E₅E_(ii)E_(iib) AlkLE_(v)E_(vi) E_(e) 881 E_(1a)E₄ AlkLE_(v)E_(vi) E_(e) 882 E_(1b)E₄ AlkLE_(v)E_(vi) E_(e) 883 E_(1a)E₅E₄ AlkLE_(v)E_(vi) E_(e) 884 E_(1b)E₅E₄ AlkLE_(v)E_(vi) E_(e) 885 E_(1a)E_(i)E₄ AlkLE_(v)E_(vi) E_(e) 886 E_(1b)E_(i)E₄ AlkLE_(v)E_(vi) E_(e) 887 E_(1a)E_(ii)E₄ AlkLE_(v)E_(vi) E_(e) 888 E_(1b)E_(ii)E₄ AlkLE_(v)E_(vi) E_(e) 889 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E_(e) 890 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E_(e) 891 E_(1a)E₅E_(i)E₄ AlkLE_(v)E_(vi) E_(e) 892 E_(1b)E₅E_(i)E₄ AlkLE_(v)E_(vi) E_(e) 893 E_(1a)E₅E_(ii)E₄ AlkLE_(v)E_(vi) E_(e) 894 E_(1b)E₅E_(ii)E₄ AlkLE_(v)E_(vi) E_(e) 895 E_(1a)E₅E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E_(e) 896 E_(1b)E₅E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E_(e) 897 E_(1a)E_(iii) AlkLE_(v)E_(vi) E_(e) 898 E_(1b)E_(iii) AlkLE_(v)E_(vi) E_(e) 899 E_(1a)E₅E_(iii) AlkLE_(v)E_(vi) E_(e) 900 E_(1b)E₅E_(iii) AlkLE_(v)E_(vi) E_(e) 901 E_(1a)E_(iii)E₄ AlkLE_(v)E_(vi) E_(e) 902 E_(1b)E_(iii)E₄ AlkLE_(v)E_(vi) E_(e) 903 E_(1a)E₅E_(iii)E₄ AlkLE_(v)E_(vi) E_(e) 904 E_(1b)E₅E_(iii)E₄ AlkLE_(v)E_(vi) E_(e) 905 E_(1a)E_(iv) AlkLE_(v)E_(vi) E_(e) 906 E_(1b)E_(iv) AlkLE_(v)E_(vi) E_(e) 907 E_(1a)E₅E_(iv) AlkLE_(v)E_(vi) E_(e) 908 E_(1b)E₅E_(iv) AlkLE_(v)E_(vi) E_(e) 909 E_(1a)E_(iv)E₄ AlkLE_(v)E_(vi) E_(e) 910 E_(1b)E_(iv)E₄ AlkLE_(v)E_(vi) E_(e) 911 E_(1a)E₅E_(iv)E₄ AlkLE_(v)E_(vi) E_(e) 912 E_(1b)E₅E_(iv)E₄ AlkLE_(v)E_(vi) E_(e) 913 E_(1a) AlkLE_(v)E_(vi) E₄* E_(e) 914 E_(1b) AlkLE_(v)E_(vi) E₄* E_(e) 915 E_(1a)E₅ AlkLE_(v)E_(vi) E₄* E_(e) 916 E_(1b)E₅ AlkLE_(v)E_(vi) E₄* E_(e) 917 E_(1a)E_(i) AlkLE_(v)E_(vi) E₄* E_(e) 918 E_(1b)E_(i) AlkLE_(v)E_(vi) E₄* E_(e) 919 E_(1a)E_(ii) AlkLE_(v)E_(vi) E₄* E_(e) 920 E_(1b)E_(ii) AlkLE_(v)E_(vi) E₄* E_(e) 921 E_(1a)E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* E_(e) 922 E_(1b)E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* E_(e) 923 E_(1a)E₅E_(i) AlkLE_(v)E_(vi) E₄* E_(e) 924 E_(1b)E₅E_(i) AlkLE_(v)E_(vi) E₄* E_(e) 925 E_(1a)E₅E_(ii) AlkLE_(v)E_(vi) E₄* E_(e) 926 E_(1b)E₅E_(ii) AlkLE_(v)E_(vi) E₄* E_(e) 927 E_(1a)E₅E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* E_(e) 928 E_(1b)E₅E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* E_(e) 929 E_(1a)E₄ AlkLE_(v)E_(vi) E₄* E_(e) 930 E_(1b)E₄ AlkLE_(v)E_(vi) E₄* E_(e) 931 E_(1a)E₅E₄ AlkLE_(v)E_(vi) E₄* E_(e) 932 E_(1b)E₅E₄ AlkLE_(v)E_(vi) E₄* E_(e) 933 E_(1a)E_(i)E₄ AlkLE_(v)E_(vi) E₄* E_(e) 934 E_(1b)E_(i)E₄ AlkLE_(v)E_(vi) E₄* E_(e) 935 E_(1a)E_(ii)E₄ AlkLE_(v)E_(vi) E₄* E_(e) 936 E_(1b)E_(ii)E₄ AlkLE_(v)E_(vi) E₄* E_(e) 937 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* E_(e) 938 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* E_(e) 939 E_(1a)E₅E_(i)E₄ AlkLE_(v)E_(vi) E₄* E_(e) 940 E_(1b)E₅E_(i)E₄ AlkLE_(v)E_(vi) E₄* E_(e) 941 E_(1a)E₅E_(ii)E₄ AlkLE_(v)E_(vi) E₄* E_(e) 942 E_(1b)E₅E_(ii)E₄ AlkLE_(v)E_(vi) E₄* E_(e) 943 E_(1a)E₅E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* E_(e) 944 E_(1b)E₅E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* E_(e) 945 E_(1a)E_(iii) AlkLE_(v)E_(vi) E₄* E_(e) 946 E_(1b)E_(iii) AlkLE_(v)E_(vi) E₄* E_(e) 947 E_(1a)E₅E_(iii) AlkLE_(v)E_(vi) E₄* E_(e) 948 E_(1b)E₅E_(iii) AlkLE_(v)E_(vi) E₄* E_(e) 949 E_(1a)E_(iii)E₄ AlkLE_(v)E_(vi) E₄* E_(e) 950 E_(1b)E_(iii)E₄ AlkLE_(v)E_(vi) E₄* E_(e) 951 E_(1a)E₅E_(iii)E₄ AlkLE_(v)E_(vi) E₄* E_(e) 952 E_(1b)E₅E_(iii)E₄ AlkLE_(v)E_(vi) E₄* E_(e) 953 E_(1a)E_(iv) AlkLE_(v)E_(vi) E₄* E_(e) 954 E_(1b)E_(iv) AlkLE_(v)E_(vi) E₄* E_(e) 955 E_(1a)E₅E_(iv) AlkLE_(v)E_(vi) E₄* E_(e) 956 E_(1b)E₅E_(iv) AlkLE_(v)E_(vi) E₄* E_(e) 957 E_(1a)E_(iv)E₄ AlkLE_(v)E_(vi) E₄* E_(e) 958 E_(1b)E_(iv)E₄ AlkLE_(v)E_(vi) E₄* E_(e) 959 E_(1a)E₅E_(iv)E₄ AlkLE_(v)E_(vi) E₄* E_(e) 960 E_(1b)E₅E_(iv)E₄ AlkLE_(v)E_(vi) E₄* E_(e) 961 E_(1a) E_(v)E_(vi) E_(f) 962 E_(1b) E_(v)E_(vi) E_(f) 963 E_(1a)E₅ E_(v)E_(vi) E_(f) 964 E_(1b)E₅ E_(v)E_(vi) E_(f) 965 E_(1a)E_(i) E_(v)E_(vi) E_(f) 966 E_(1b)E_(i) E_(v)E_(vi) E_(f) 967 E_(1a)E_(ii) E_(v)E_(vi) E_(f) 968 E_(1b)E_(ii) E_(v)E_(vi) E_(f) 969 E_(1a)E_(ii)E_(iib) E_(v)E_(vi) E_(f) 970 E_(1b)E_(ii)E_(iib) E_(v)E_(vi) E_(f) 971 E_(1a)E₅E_(i) E_(v)E_(vi) E_(f) 972 E_(1b)E₅E_(i) E_(v)E_(vi) E_(f) 973 E_(1a)E₅E_(ii) E_(v)E_(vi) E_(f) 974 E_(1b)E₅E_(ii) E_(v)E_(vi) E_(f) 975 E_(1a)E₅E_(ii)E_(iib) E_(v)E_(vi) E_(f) 976 E_(1b)E₅E_(ii)E_(iib) E_(v)E_(vi) E_(f) 977 E_(1a)E₄ E_(v)E_(vi) E_(f) 978 E_(1b)E₄ E_(v)E_(vi) E_(f) 979 E_(1a)E₅E₄ E_(v)E_(vi) E_(f) 980 E_(1b)E₅E₄ E_(v)E_(vi) E_(f) 981 E_(1a)E_(i)E₄ E_(v)E_(vi) E_(f) 982 E_(1b)E_(i)E₄ E_(v)E_(vi) E_(f) 983 E_(1a)E_(ii)E₄ E_(v)E_(vi) E_(f) 984 E_(1b)E_(ii)E₄ E_(v)E_(vi) E_(f) 985 E_(1a)E_(ii)E_(iib)E₄ E_(v)E_(vi) E_(f) 986 E_(1b)E_(ii)E_(iib)E₄ E_(v)E_(vi) E_(f) 987 E_(1a)E₅E_(i)E₄ E_(v)E_(vi) E_(f) 988 E_(1b)E₅E_(i)E₄ E_(v)E_(vi) E_(f) 989 E_(1a)E₅E_(ii)E₄ E_(v)E_(vi) E_(f) 990 E_(1b)E₅E_(ii)E₄ E_(v)E_(vi) E_(f) 991 E_(1a)E₅E_(ii)E_(iib)E₄ E_(v)E_(vi) E_(f) 992 E_(1b)E₅E_(ii)E_(iib)E₄ E_(v)E_(vi) E_(f) 993 E_(1a)E_(iii) E_(v)E_(vi) E_(f) 994 E_(1b)E_(iii) E_(v)E_(vi) E_(f) 995 E_(1a)E₅E_(iii) E_(v)E_(vi) E_(f) 996 E_(1b)E₅E_(iii) E_(v)E_(vi) E_(f) 997 E_(1a)E_(iii)E₄ E_(v)E_(vi) E_(f) 998 E_(1b)E_(iii)E₄ E_(v)E_(vi) E_(f) 999 E_(1a)E₅E_(iii)E₄ E_(v)E_(vi) E_(f) 1000 E_(1b)E₅E_(iii)E₄ E_(v)E_(vi) E_(f) 1001 E_(1a)E_(iv) E_(v)E_(vi) E_(f) 1002 E_(1b)E_(iv) E_(v)E_(vi) E_(f) 1003 E_(1a)E₅E_(iv) E_(v)E_(vi) E_(f) 1004 E_(1b)E₅E_(iv) E_(v)E_(vi) E_(f) 1005 E_(1a)E_(iv)E₄ E_(v)E_(vi) E_(f) 1006 E_(1b)E_(iv)E₄ E_(v)E_(vi) E_(f) 1007 E_(1a)E₅E_(iv)E₄ E_(v)E_(vi) E_(f) 1008 E_(1b)E₅E_(iv)E₄ E_(v)E_(vi) E_(f) 1009 E_(1a) E_(v)E_(vi) E₄* E_(f) 1010 E_(1b) E_(v)E_(vi) E₄* E_(f) 1011 E_(1a)E₅ E_(v)E_(vi) E₄* E_(f) 1012 E_(1b)E₅ E_(v)E_(vi) E₄* E_(f) 1013 E_(1a)E_(i) E_(v)E_(vi) E₄* E_(f) 1014 E_(1b)E_(i) E_(v)E_(vi) E₄* E_(f) 1015 E_(1a)E_(ii) E_(v)E_(vi) E₄* E_(f) 1016 E_(1b)E_(ii) E_(v)E_(vi) E₄* E_(f) 1017 E_(1a)E_(ii)E_(iib) E_(v)E_(vi) E₄* E_(f) 1018 E_(1b)E_(ii)E_(iib) E_(v)E_(vi) E₄* E_(f) 1019 E_(1a)E₅E_(i) E_(v)E_(vi) E₄* E_(f) 1020 E_(1b)E₅E_(i) E_(v)E_(vi) E₄* E_(f) 1021 E_(1a)E₅E_(ii) E_(v)E_(vi) E₄* E_(f) 1022 E_(1b)E₅E_(ii) E_(v)E_(vi) E₄* E_(f) 1023 E_(1a)E₅E_(ii)E_(iib) E_(v)E_(vi) E₄* E_(f) 1024 E_(1b)E₅E_(ii)E_(iib) E_(v)E_(vi) E₄* E_(f) 1025 E_(1a)E₄ E_(v)E_(vi) E₄* E_(f) 1026 E_(1b)E₄ E_(v)E_(vi) E₄* E_(f) 1027 E_(1a)E₅E₄ E_(v)E_(vi) E₄* E_(f) 1028 E_(1b)E₅E₄ E_(v)E_(vi) E₄* E_(f) 1029 E_(1a)E_(i)E₄ E_(v)E_(vi) E₄* E_(f) 1030 E_(1b)E_(i)E₄ E_(v)E_(vi) E₄* E_(f) 1031 E_(1a)E_(ii)E₄ E_(v)E_(vi) E₄* E_(f) 1032 E_(1b)E_(ii)E₄ E_(v)E_(vi) E₄* E_(f) 1033 E_(1a)E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* E_(f) 1034 E_(1b)E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* E_(f) 1035 E_(1a)E₅E_(i)E₄ E_(v)E_(vi) E₄* E_(f) 1036 E_(1b)E₅E_(i)E₄ E_(v)E_(vi) E₄* E_(f) 1037 E_(1a)E₅E_(ii)E₄ E_(v)E_(vi) E₄* E_(f) 1038 E_(1b)E₅E_(ii)E₄ E_(v)E_(vi) E₄* E_(f) 1039 E_(1a)E₅E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* E_(f) 1040 E_(1b)E₅E_(ii)E_(iib)E₄ E_(v)E_(vi) E₄* E_(f) 1041 E_(1a)E_(iii) E_(v)E_(vi) E₄* E_(f) 1042 E_(1b)E_(iii) E_(v)E_(vi) E₄* E_(f) 1043 E_(1a)E₅E_(iii) E_(v)E_(vi) E₄* E_(f) 1044 E_(1b)E₅E_(iii) E_(v)E_(vi) E₄* E_(f) 1045 E_(1a)E_(iii)E₄ E_(v)E_(vi) E₄* E_(f) 1046 E_(1b)E_(iii)E₄ E_(v)E_(vi) E₄* E_(f) 1047 E_(1a)E₅E_(iii)E₄ E_(v)E_(vi) E₄* E_(f) 1048 E_(1b)E₅E_(iii)E₄ E_(v)E_(vi) E₄* E_(f) 1049 E_(1a)E_(iv) E_(v)E_(vi) E₄* E_(f) 1050 E_(1b)E_(iv) E_(v)E_(vi) E₄* E_(f) 1051 E_(1a)E₅E_(iv) E_(v)E_(vi) E₄* E_(f) 1052 E_(1b)E₅E_(iv) E_(v)E_(vi) E₄* E_(f) 1053 E_(1a)E_(iv)E₄ E_(v)E_(vi) E₄* E_(f) 1054 E_(1b)E_(iv)E₄ E_(v)E_(vi) E₄* E_(f) 1055 E_(1a)E₅E_(iv)E₄ E_(v)E_(vi) E₄* E_(f) 1056 E_(1b)E₅E_(iv)E₄ E_(v)E_(vi) E₄* E_(f) 1057 E_(1a) AlkLE_(v)E_(vi) E_(f) 1058 E_(1b) AlkLE_(v)E_(vi) E_(f) 1059 E_(1a)E₅ AlkLE_(v)E_(vi) E_(f) 1060 E_(1b)E₅ AlkLE_(v)E_(vi) E_(f) 1061 E_(1a)E_(i) AlkLE_(v)E_(vi) E_(f) 1062 E_(1b)E_(i) AlkLE_(v)E_(vi) E_(f) 1063 E_(1a)E_(ii) AlkLE_(v)E_(vi) E_(f) 1064 E_(1b)E_(ii) AlkLE_(v)E_(vi) E_(f) 1065 E_(1a)E_(ii)E_(iib) AlkLE_(v)E_(vi) E_(f) 1066 E_(1b)E_(ii)E_(iib) AlkLE_(v)E_(vi) E_(f) 1067 E_(1a)E₅E_(i) AlkLE_(v)E_(vi) E_(f) 1068 E_(1b)E₅E_(i) AlkLE_(v)E_(vi) E_(f) 1069 E_(1a)E₅E_(ii) AlkLE_(v)E_(vi) E_(f) 1070 E_(1b)E₅E_(ii) AlkLE_(v)E_(vi) E_(f) 1071 E_(1a)E₅E_(ii)E_(iib) AlkLE_(v)E_(vi) E_(f) 1072 E_(1b)E₅E_(ii)E_(iib) AlkLE_(v)E_(vi) E_(f) 1073 E_(1a)E₄ AlkLE_(v)E_(vi) E_(f) 1074 E_(1b)E₄ AlkLE_(v)E_(vi) E_(f) 1075 E_(1a)E₅E₄ AlkLE_(v)E_(vi) E_(f) 1076 E_(1b)E₅E₄ AlkLE_(v)E_(vi) E_(f) 1077 E_(1a)E_(i)E₄ AlkLE_(v)E_(vi) E_(f) 1078 E_(1b)E_(i)E₄ AlkLE_(v)E_(vi) E_(f) 1079 E_(1a)E_(ii)E₄ AlkLE_(v)E_(vi) E_(f) 1080 E_(1b)E_(ii)E₄ AlkLE_(v)E_(vi) E_(f) 1081 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E_(f) 1082 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E_(f) 1083 E_(1a)E₅E_(i)E₄ AlkLE_(v)E_(vi) E_(f) 1084 E_(1b)E₅E_(i)E₄ AlkLE_(v)E_(vi) E_(f) 1085 E_(1a)E₅E_(ii)E₄ AlkLE_(v)E_(vi) E_(f) 1086 E_(1b)E₅E_(ii)E₄ AlkLE_(v)E_(vi) E_(f) 1087 E_(1a)E₅E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E_(f) 1088 E_(1b)E₅E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E_(f) 1089 E_(1a)E_(iii) AlkLE_(v)E_(vi) E_(f) 1090 E_(1b)E_(iii) AlkLE_(v)E_(vi) E_(f) 1091 E_(1a)E₅E_(iii) AlkLE_(v)E_(vi) E_(f) 1092 E_(1b)E₅E_(iii) AlkLE_(v)E_(vi) E_(f) 1093 E_(1a)E_(iii)E₄ AlkLE_(v)E_(vi) E_(f) 1094 E_(1b)E_(iii)E₄ AlkLE_(v)E_(vi) E_(f) 1095 E_(1a)E₅E_(iii)E₄ AlkLE_(v)E_(vi) E_(f) 1096 E_(1b)E₅E_(iii)E₄ AlkLE_(v)E_(vi) E_(f) 1097 E_(1a)E_(iv) AlkLE_(v)E_(vi) E_(f) 1098 E_(1b)E_(iv) AlkLE_(v)E_(vi) E_(f) 1099 E_(1a)E₅E_(iv) AlkLE_(v)E_(vi) E_(f) 1100 E_(1b)E₅E_(iv) AlkLE_(v)E_(vi) E_(f) 1101 E_(1a)E_(iv)E₄ AlkLE_(v)E_(vi) E_(f) 1102 E_(1b)E_(iv)E₄ AlkLE_(v)E_(vi) E_(f) 1103 E_(1a)E₅E_(iv)E₄ AlkLE_(v)E_(vi) E_(f) 1104 E_(1b)E₅E_(iv)E₄ AlkLE_(v)E_(vi) E_(f) 1105 E_(1a) AlkLE_(v)E_(vi) E₄* E_(f) 1106 E_(1b) AlkLE_(v)E_(vi) E₄* E_(f) 1107 E_(1a)E₅ AlkLE_(v)E_(vi) E₄* E_(f) 1108 E_(1b)E₅ AlkLE_(v)E_(vi) E₄* E_(f) 1109 E_(1a)E_(i) AlkLE_(v)E_(vi) E₄* E_(f) 1110 E_(1b)E_(i) AlkLE_(v)E_(vi) E₄* E_(f) 1111 E_(1a)E_(ii) AlkLE_(v)E_(vi) E₄* E_(f) 1112 E_(1b)E_(ii) AlkLE_(v)E_(vi) E₄* E_(f) 1113 E_(1a)E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* E_(f) 1114 E_(1b)E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* E_(f) 1115 E_(1a)E₅E_(i) AlkLE_(v)E_(vi) E₄* E_(f) 1116 E_(1b)E₅E_(i) AlkLE_(v)E_(vi) E₄* E_(f) 1117 E_(1a)E₅E_(ii) AlkLE_(v)E_(vi) E₄* E_(f) 1118 E_(1b)E₅E_(ii) AlkLE_(v)E_(vi) E₄* E_(f) 1119 E_(1a)E₅E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* E_(f) 1120 E_(1b)E₅E_(ii)E_(iib) AlkLE_(v)E_(vi) E₄* E_(f) 1121 E_(1a)E₄ AlkLE_(v)E_(vi) E₄* E_(f) 1122 E_(1b)E₄ AlkLE_(v)E_(vi) E₄* E_(f) 1123 E_(1a)E₅E₄ AlkLE_(v)E_(vi) E₄* E_(f) 1124 E_(1b)E₅E₄ AlkLE_(v)E_(vi) E₄* E_(f) 1125 E_(1a)E_(i)E₄ AlkLE_(v)E_(vi) E₄* E_(f) 1126 E_(1b)E_(i)E₄ AlkLE_(v)E_(vi) E₄* E_(f) 1127 E_(1a)E_(ii)E₄ AlkLE_(v)E_(vi) E₄* E_(f) 1128 E_(1b)E_(ii)E₄ AlkLE_(v)E_(vi) E₄* E_(f) 1129 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* E_(f) 1130 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* E_(f) 1131 E_(1a)E₅E_(i)E₄ AlkLE_(v)E_(vi) E₄* E_(f) 1132 E_(1b)E₅E_(i)E₄ AlkLE_(v)E_(vi) E₄* E_(f) 1133 E_(1a)E₅E_(ii)E₄ AlkLE_(v)E_(vi) E₄* E_(f) 1134 E_(1b)E₅E_(ii)E₄ AlkLE_(v)E_(vi) E₄* E_(f) 1135 E_(1a)E₅E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* E_(f) 1136 E_(1b)E₅E_(ii)E_(iib)E₄ AlkLE_(v)E_(vi) E₄* E_(f) 1137 E_(1a)E_(iii) AlkLE_(v)E_(vi) E₄* E_(f) 1138 E_(1b)E_(iii) AlkLE_(v)E_(vi) E₄* E_(f) 1139 E_(1a)E₅E_(iii) AlkLE_(v)E_(vi) E₄* E_(f) 1140 E_(1b)E₅E_(iii) AlkLE_(v)E_(vi) E₄* E_(f) 1141 E_(1a)E_(iii)E₄ AlkLE_(v)E_(vi) E₄* E_(f) 1142 E_(1b)E_(iii)E₄ AlkLE_(v)E_(vi) E₄* E_(f) 1143 E_(1a)E₅E_(iii)E₄ AlkLE_(v)E_(vi) E₄* E_(f) 1144 E_(1b)E₅E_(iii)E₄ AlkLE_(v)E_(vi) E₄* E_(f) 1145 E_(1a)E_(iv) AlkLE_(v)E_(vi) E₄* E_(f) 1146 E_(1b)E_(iv) AlkLE_(v)E_(vi) E₄* E_(f) 1147 E_(1a)E₅E_(iv) AlkLE_(v)E_(vi) E₄* E_(f) 1148 E_(1b)E₅E_(iv) AlkLE_(v)E_(vi) E₄* E_(f) 1149 E_(1a)E_(iv)E₄ AlkLE_(v)E_(vi) E₄* E_(f) 1150 E_(1b)E_(iv)E₄ AlkLE_(v)E_(vi) E₄* E_(f) 1151 E_(1a)E₅E_(iv)E₄ AlkLE_(v)E_(vi) E₄* E_(f) 1152 E_(1b)E₅E_(iv)E₄ AlkLE_(v)E_(vi) E₄* E_(f) 1153 E_(1a) E_(vii) 1154 E_(1b) E_(vii) 1155 E_(1a)E₅ E_(vii) 1156 E_(1b)E₅ E_(vii) 1157 E_(1a)E_(i) E_(vii) 1158 E_(1b)E_(i) E_(vii) 1159 E_(1a)E_(ii) E_(vii) 1160 E_(1b)E_(ii) E_(vii) 1161 E_(1a)E_(ii)E_(iib) E_(vii) 1162 E_(1b)E_(ii)E_(iib) E_(vii) 1163 E_(1a)E₅E_(i) E_(vii) 1164 E_(1b)E₅E_(i) E_(vii) 1165 E_(1a)E₅E_(ii) E_(vii) 1166 E_(1b)E₅E_(ii) E_(vii) 1167 E_(1a)E₅E_(ii)E_(iib) E_(vii) 1168 E_(1b)E₅E_(ii)E_(iib) E_(vii) 1169 E_(1a)E₄ E_(vii) 1170 E_(1b)E₄ E_(vii) 1171 E_(1a)E₅E₄ E_(vii) 1172 E_(1b)E₅E₄ E_(vii) 1173 E_(1a)E_(i)E₄ E_(vii) 1174 E_(1b)E_(i)E₄ E_(vii) 1175 E_(1a)E_(ii)E₄ E_(vii) 1176 E_(1b)E_(ii)E₄ E_(vii) 1177 E_(1a)E_(ii)E_(iib)E₄ E_(vii) 1178 E_(1b)E_(ii)E_(iib)E₄ E_(vii) 1179 E_(1a)E₅E_(i)E₄ E_(vii) 1180 E_(1b)E₅E_(i)E₄ E_(vii) 1181 E_(1a)E₅E_(ii)E₄ E_(vii) 1182 E_(1b)E₅E_(ii)E₄ E_(vii) 1183 E_(1a)E₅E_(ii)E_(iib)E₄ E_(vii) 1184 E_(1b)E₅E_(ii)E_(iib)E₄ E_(vii) 1185 E_(1a)E_(iii) E_(vii) 1186 E_(1b)E_(iii) E_(vii) 1187 E_(1a)E₅E_(iii) E_(vii) 1188 E_(1b)E₅E_(iii) E_(vii) 1189 E_(1a)E_(iii)E₄ E_(vii) 1190 E_(1b)E_(iii)E₄ E_(vii) 1191 E_(1a)E₅E_(iii)E₄ E_(vii) 1192 E_(1b)E₅E_(iii)E₄ E_(vii) 1193 E_(1a)E_(iv) E_(vii) 1194 E_(1b)E_(iv) E_(vii) 1195 E_(1a)E₅E_(iv) E_(vii) 1196 E_(1b)E₅E_(iv) E_(vii) 1197 E_(1a)E_(iv)E₄ E_(vii) 1198 E_(1b)E_(iv)E₄ E_(vii) 1199 E_(1a)E₅E_(iv)E₄ E_(vii) 1200 E_(1b)E₅E_(iv)E₄ E_(vii) 1201 E_(1a) E_(vii) E₄* 1202 E_(1b) E_(vii) E₄* 1203 E_(1a)E₅ E_(vii) E₄* 1204 E_(1b)E₅ E_(vii) E₄* 1205 E_(1a)E_(i) E_(vii) E₄* 1206 E_(1b)E_(i) E_(vii) E₄* 1207 E_(1a)E_(ii) E_(vii) E₄* 1208 E_(1b)E_(ii) E_(vii) E₄* 1209 E_(1a)E_(ii)E_(iib) E_(vii) E₄* 1210 E_(1b)E_(ii)E_(iib) E_(vii) E₄* 1211 E_(1a)E₅E_(i) E_(vii) E₄* 1212 E_(1b)E₅E_(i) E_(vii) E₄* 1213 E_(1a)E₅E_(ii) E_(vii) E₄* 1214 E_(1b)E₅E_(ii) E_(vii) E₄* 1215 E_(1a)E₅E_(ii)E_(iib) E_(vii) E₄* 1216 E_(1b)E₅E_(ii)E_(iib) E_(vii) E₄* 1217 E_(1a)E₄ E_(vii) E₄* 1218 E_(1b)E₄ E_(vii) E₄* 1219 E_(1a)E₅E₄ E_(vii) E₄* 1220 E_(1b)E₅E₄ E_(vii) E₄* 1221 E_(1a)E_(i)E₄ E_(vii) E₄* 1222 E_(1b)E_(i)E₄ E_(vii) E₄* 1223 E_(1a)E_(ii)E₄ E_(vii) E₄* 1224 E_(1b)E_(ii)E₄ E_(vii) E₄* 1225 E_(1a)E_(ii)E_(iib)E₄ E_(vii) E₄* 1226 E_(1b)E_(ii)E_(iib)E₄ E_(vii) E₄* 1227 E_(1a)E₅E_(i)E₄ E_(vii) E₄* 1228 E_(1b)E₅E_(i)E₄ E_(vii) E₄* 1229 E_(1a)E₅E_(ii)E₄ E_(vii) E₄* 1230 E_(1b)E₅E_(ii)E₄ E_(vii) E₄* 1231 E_(1a)E₅E_(ii)E_(iib)E₄ E_(vii) E₄* 1232 E_(1b)E₅E_(ii)E_(iib)E₄ E_(vii) E₄* 1233 E_(1a)E_(iii) E_(vii) E₄* 1234 E_(1b)E_(iii) E_(vii) E₄* 1235 E_(1a)E₅E_(iii) E_(vii) E₄* 1236 E_(1b)E₅E_(iii) E_(vii) E₄* 1237 E_(1a)E_(iii)E₄ E_(vii) E₄* 1238 E_(1b)E_(iii)E₄ E_(vii) E₄* 1239 E_(1a)E₅E_(iii)E₄ E_(vii) E₄* 1240 E_(1b)E₅E_(iii)E₄ E_(vii) E₄* 1241 E_(1a)E_(iv) E_(vii) E₄* 1242 E_(1b)E_(iv) E_(vii) E₄* 1243 E_(1a)E₅E_(iv) E_(vii) E₄* 1244 E_(1b)E₅E_(iv) E_(vii) E₄* 1245 E_(1a)E_(iv)E₄ E_(vii) E₄* 1246 E_(1b)E_(iv)E₄ E_(vii) E₄* 1247 E_(1a)E₅E_(iv)E₄ E_(vii) E₄* 1248 E_(1b)E₅E_(iv)E₄ E_(vii) E₄* 1249 E_(1a) AlkLE_(vii) 1250 E_(1b) AlkLE_(vii) 1251 E_(1a)E₅ AlkLE_(vii) 1252 E_(1b)E₅ AlkLE_(vii) 1253 E_(1a)E_(i) AlkLE_(vii) 1254 E_(1b)E_(i) AlkLE_(vii) 1255 E_(1a)E_(ii) AlkLE_(vii) 1256 E_(1b)E_(ii) AlkLE_(vii) 1257 E_(1a)E_(ii)E_(iib) AlkLE_(vii) 1258 E_(1b)E_(ii)E_(iib) AlkLE_(vii) 1259 E_(1a)E₅E_(i) AlkLE_(vii) 1260 E_(1b)E₅E_(i) AlkLE_(vii) 1261 E_(1a)E₅E_(ii) AlkLE_(vii) 1262 E_(1b)E₅E_(ii) AlkLE_(vii) 1263 E_(1a)E₅E_(ii)E_(iib) AlkLE_(vii) 1264 E_(1b)E₅E_(ii)E_(iib) AlkLE_(vii) 1265 E_(1a)E₄ AlkLE_(vii) 1266 E_(1b)E₄ AlkLE_(vii) 1267 E_(1a)E₅E₄ AlkLE_(vii) 1268 E_(1b)E₅E₄ AlkLE_(vii) 1269 E_(1a)E_(i)E₄ AlkLE_(vii) 1270 E_(1b)E_(i)E₄ AlkLE_(vii) 1271 E_(1a)E_(ii)E₄ AlkLE_(vii) 1272 E_(1b)E_(ii)E₄ AlkLE_(vii) 1273 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(vii) 1274 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(vii) 1275 E_(1a)E₅E_(i)E₄ AlkLE_(vii) 1276 E_(1b)E₅E_(i)E₄ AlkLE_(vii) 1277 E_(1a)E₅E_(ii)E₄ AlkLE_(vii) 1278 E_(1b)E₅E_(ii)E₄ AlkLE_(vii) 1279 E_(1a)E₅E_(ii)E_(iib)E₄ AlkLE_(vii) 1280 E_(1b)E₅E_(ii)E_(iib)E₄ AlkLE_(vii) 1281 E_(1a)E_(iii) AlkLE_(vii) 1282 E_(1b)E_(iii) AlkLE_(vii) 1283 E_(1a)E₅E_(iii) AlkLE_(vii) 1284 E_(1b)E₅E_(iii) AlkLE_(vii) 1285 E_(1a)E_(iii)E₄ AlkLE_(vii) 1286 E_(1b)E_(iii)E₄ AlkLE_(vii) 1287 E_(1a)E₅E_(iii)E₄ AlkLE_(vii) 1288 E_(1b)E₅E_(iii)E₄ AlkLE_(vii) 1289 E_(1a)E_(iv) AlkLE_(vii) 1290 E_(1b)E_(iv) AlkLE_(vii) 1291 E_(1a)E₅E_(iv) AlkLE_(vii) 1292 E_(1b)E₅E_(iv) AlkLE_(vii) 1293 E_(1a)E_(iv)E₄ AlkLE_(vii) 1294 E_(1b)E_(iv)E₄ AlkLE_(vii) 1295 E_(1a)E₅E_(iv)E₄ AlkLE_(vii) 1296 E_(1b)E₅E_(iv)E₄ AlkLE_(vii) 1297 E_(1a) AlkLE_(vii) E₄* 1298 E_(1b) AlkLE_(vii) E₄* 1299 E_(1a)E₅ AlkLE_(vii) E₄* 1300 E_(1b)E₅ AlkLE_(vii) E₄* 1301 E_(1a)E_(i) AlkLE_(vii) E₄* 1302 E_(1b)E_(i) AlkLE_(vii) E₄* 1303 E_(1a)E_(ii) AlkLE_(vii) E₄* 1304 E_(1b)E_(ii) AlkLE_(vii) E₄* 1305 E_(1a)E_(ii)E_(iib) AlkLE_(vii) E₄* 1306 E_(1b)E_(ii)E_(iib) AlkLE_(vii) E₄* 1307 E_(1a)E₅E_(i) AlkLE_(vii) E₄* 1308 E_(1b)E₅E_(i) AlkLE_(vii) E₄* 1309 E_(1a)E₅E_(ii) AlkLE_(vii) E₄* 1310 E_(1b)E₅E_(ii) AlkLE_(vii) E₄* 1311 E_(1a)E₅E_(ii)E_(iib) AlkLE_(vii) E₄* 1312 E_(1b)E₅E_(ii)E_(iib) AlkLE_(vii) E₄* 1313 E_(1a)E₄ AlkLE_(vii) E₄* 1314 E_(1b)E₄ AlkLE_(vii) E₄* 1315 E_(1a)E₅E₄ AlkLE_(vii) E₄* 1316 E_(1b)E₅E₄ AlkLE_(vii) E₄* 1317 E_(1a)E_(i)E₄ AlkLE_(vii) E₄* 1318 E_(1b)E_(i)E₄ AlkLE_(vii) E₄* 1319 E_(1a)E_(ii)E₄ AlkLE_(vii) E₄* 1320 E_(1b)E_(ii)E₄ AlkLE_(vii) E₄* 1321 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* 1322 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* 1323 E_(1a)E₅E_(i)E₄ AlkLE_(vii) E₄* 1324 E_(1b)E₅E_(i)E₄ AlkLE_(vii) E₄* 1325 E_(1a)E₅E_(ii)E₄ AlkLE_(vii) E₄* 1326 E_(1b)E₅E_(ii)E₄ AlkLE_(vii) E₄* 1327 E_(1a)E₅E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* 1328 E_(1b)E₅E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* 1329 E_(1a)E_(iii) AlkLE_(vii) E₄* 1330 E_(1b)E_(iii) AlkLE_(vii) E₄* 1331 E_(1a)E₅E_(iii) AlkLE_(vii) E₄* 1332 E_(1b)E₅E_(iii) AlkLE_(vii) E₄* 1333 E_(1a)E_(iii)E₄ AlkLE_(vii) E₄* 1334 E_(1b)E_(iii)E₄ AlkLE_(vii) E₄* 1335 E_(1a)E₅E_(iii)E₄ AlkLE_(vii) E₄* 1336 E_(1b)E₅E_(iii)E₄ AlkLE_(vii) E₄* 1337 E_(1a)E_(iv) AlkLE_(vii) E₄* 1338 E_(1b)E_(iv) AlkLE_(vii) E₄* 1339 E_(1a)E₅E_(iv) AlkLE_(vii) E₄* 1340 E_(1b)E₅E_(iv) AlkLE_(vii) E₄* 1341 E_(1a)E_(iv)E₄ AlkLE_(vii) E₄* 1342 E_(1b)E_(iv)E₄ AlkLE_(vii) E₄* 1343 E_(1a)E₅E_(iv)E₄ AlkLE_(vii) E₄* 1344 E_(1b)E₅E_(iv)E₄ AlkLE_(vii) E₄* 1345 E_(1a) E_(vii) E_(a) 1346 E_(1b) E_(vii) E_(a) 1347 E_(1a)E₅ E_(vii) E_(a) 1348 E_(1b)E₅ E_(vii) E_(a) 1349 E_(1a)E_(i) E_(vii) E_(a) 1350 E_(1b)E_(i) E_(vii) E_(a) 1351 E_(1a)E_(ii) E_(vii) E_(a) 1352 E_(1b)E_(ii) E_(vii) E_(a) 1353 E_(1a)E_(ii)E_(iib) E_(vii) E_(a) 1354 E_(1b)E_(ii)E_(iib) E_(vii) E_(a) 1355 E_(1a)E₅E_(i) E_(vii) E_(a) 1356 E_(1b)E₅E_(i) E_(vii) E_(a) 1357 E_(1a)E₅E_(ii) E_(vii) E_(a) 1358 E_(1b)E₅E_(ii) E_(vii) E_(a) 1359 E_(1a)E₅E_(ii)E_(iib) E_(vii) E_(a) 1360 E_(1b)E₅E_(ii)E_(iib) E_(vii) E_(a) 1361 E_(1a)E₄ E_(vii) E_(a) 1362 E_(1b)E₄ E_(vii) E_(a) 1363 E_(1a)E₅E₄ E_(vii) E_(a) 1364 E_(1b)E₅E₄ E_(vii) E_(a) 1365 E_(1a)E_(i)E₄ E_(vii) E_(a) 1366 E_(1b)E_(i)E₄ E_(vii) E_(a) 1367 E_(1a)E_(ii)E₄ E_(vii) E_(a) 1368 E_(1b)E_(ii)E₄ E_(vii) E_(a) 1369 E_(1a)E_(ii)E_(iib)E₄ E_(vii) E_(a) 1370 E_(1b)E_(ii)E_(iib)E₄ E_(vii) E_(a) 1371 E_(1a)E₅E_(i)E₄ E_(vii) E_(a) 1372 E_(1b)E₅E_(i)E₄ E_(vii) E_(a) 1373 E_(1a)E₅E_(ii)E₄ E_(vii) E_(a) 1374 E_(1b)E₅E_(ii)E₄ E_(vii) E_(a) 1375 E_(1a)E₅E_(ii)E_(iib)E₄ E_(vii) E_(a) 1376 E_(1b)E₅E_(ii)E_(iib)E₄ E_(vii) E_(a) 1377 E_(1a)E_(iii) E_(vii) E_(a) 1378 E_(1b)E_(iii) E_(vii) E_(a) 1379 E_(1a)E₅E_(iii) E_(vii) E_(a) 1380 E_(1b)E₅E_(iii) E_(vii) E_(a) 1381 E_(1a)E_(iii)E₄ E_(vii) E_(a) 1382 E_(1b)E_(iii)E₄ E_(vii) E_(a) 1383 E_(1a)E₅E_(iii)E₄ E_(vii) E_(a) 1384 E_(1b)E₅E_(iii)E₄ E_(vii) E_(a) 1385 E_(1a)E_(iv) E_(vii) E_(a) 1386 E_(1b)E_(iv) E_(vii) E_(a) 1387 E_(1a)E₅E_(iv) E_(vii) E_(a) 1388 E_(1b)E₅E_(iv) E_(vii) E_(a) 1389 E_(1a)E_(iv)E₄ E_(vii) E_(a) 1390 E_(1b)E_(iv)E₄ E_(vii) E_(a) 1391 E_(1a)E₅E_(iv)E₄ E_(vii) E_(a) 1392 E_(1b)E₅E_(iv)E₄ E_(vii) E_(a) 1393 E_(1a) E_(vii) E₄* E_(a) 1394 E_(1b) E_(vii) E₄* E_(a) 1395 E_(1a)E₅ E_(vii) E₄* E_(a) 1396 E_(1b)E₅ E_(vii) E₄* E_(a) 1397 E_(1a)E_(i) E_(vii) E₄* E_(a) 1398 E_(1b)E_(i) E_(vii) E₄* E_(a) 1399 E_(1a)E_(ii) E_(vii) E₄* E_(a) 1400 E_(1b)E_(ii) E_(vii) E₄* E_(a) 1401 E_(1a)E_(ii)E_(iib) E_(vii) E₄* E_(a) 1402 E_(1b)E_(ii)E_(iib) E_(vii) E₄* E_(a) 1403 E_(1a)E₅E_(i) E_(vii) E₄* E_(a) 1404 E_(1b)E₅E_(i) E_(vii) E₄* E_(a) 1405 E_(1a)E₅E_(ii) E_(vii) E₄* E_(a) 1406 E_(1b)E₅E_(ii) E_(vii) E₄* E_(a) 1407 E_(1a)E₅E_(ii)E_(iib) E_(vii) E₄* E_(a) 1408 E_(1b)E₅E_(ii)E_(iib) E_(vii) E₄* E_(a) 1409 E_(1a)E₄ E_(vii) E₄* E_(a) 1410 E_(1b)E₄ E_(vii) E₄* E_(a) 1411 E_(1a)E₅E₄ E_(vii) E₄* E_(a) 1412 E_(1b)E₅E₄ E_(vii) E₄* E_(a) 1413 E_(1a)E_(i)E₄ E_(vii) E₄* E_(a) 1414 E_(1b)E_(i)E₄ E_(vii) E₄* E_(a) 1415 E_(1a)E_(ii)E₄ E_(vii) E₄* E_(a) 1416 E_(1b)E_(ii)E₄ E_(vii) E₄* E_(a) 1417 E_(1a)E_(ii)E_(iib)E₄ E_(vii) E₄* E_(a) 1418 E_(1b)E_(ii)E_(iib)E₄ E_(vii) E₄* E_(a) 1419 E_(1a)E₅E_(i)E₄ E_(vii) E₄* E_(a) 1420 E_(1b)E₅E_(i)E₄ E_(vii) E₄* E_(a) 1421 E_(1a)E₅E_(ii)E₄ E_(vii) E₄* E_(a) 1422 E_(1b)E₅E_(ii)E₄ E_(vii) E₄* E_(a) 1423 E_(1a)E₅E_(ii)E_(iib)E₄ E_(vii) E₄* E_(a) 1424 E_(1b)E₅E_(ii)E_(iib)E₄ E_(vii) E₄* E_(a) 1425 E_(1a)E_(iii) E_(vii) E₄* E_(a) 1426 E_(1b)E_(iii) E_(vii) E₄* E_(a) 1427 E_(1a)E₅E_(iii) E_(vii) E₄* E_(a) 1428 E_(1b)E₅E_(iii) E_(vii) E₄* E_(a) 1429 E_(1a)E_(iii)E₄ E_(vii) E₄* E_(a) 1430 E_(1b)E_(iii)E₄ E_(vii) E₄* E_(a) 1431 E_(1a)E₅E_(iii)E₄ E_(vii) E₄* E_(a) 1432 E_(1b)E₅E_(iii)E₄ E_(vii) E₄* E_(a) 1433 E_(1a)E_(iv) E_(vii) E₄* E_(a) 1434 E_(1b)E_(iv) E_(vii) E₄* E_(a) 1435 E_(1a)E₅E_(iv) E_(vii) E₄* E_(a) 1436 E_(1b)E₅E_(iv) E_(vii) E₄* E_(a) 1437 E_(1a)E_(iv)E₄ E_(vii) E₄* E_(a) 1438 E_(1b)E_(iv)E₄ E_(vii) E₄* E_(a) 1439 E_(1a)E₅E_(iv)E₄ E_(vii) E₄* E_(a) 1440 E_(1b)E₅E_(iv)E₄ E_(vii) E₄* E_(a) 1441 E_(1a) AlkLE_(vii) E_(a) 1442 E_(1b) AlkLE_(vii) E_(a) 1443 E_(1a)E₅ AlkLE_(vii) E_(a) 1444 E_(1b)E₅ AlkLE_(vii) E_(a) 1445 E_(1a)E_(i) AlkLE_(vii) E_(a) 1446 E_(1b)E_(i) AlkLE_(vii) E_(a) 1447 E_(1a)E_(ii) AlkLE_(vii) E_(a) 1448 E_(1b)E_(ii) AlkLE_(vii) E_(a) 1449 E_(1a)E_(ii)E_(iib) AlkLE_(vii) E_(a) 1450 E_(1b)E_(ii)E_(iib) AlkLE_(vii) E_(a) 1451 E_(1a)E₅E_(i) AlkLE_(vii) E_(a) 1452 E_(1b)E₅E_(i) AlkLE_(vii) E_(a) 1453 E_(1a)E₅E_(ii) AlkLE_(vii) E_(a) 1454 E_(1b)E₅E_(ii) AlkLE_(vii) E_(a) 1455 E_(1a)E₅E_(ii)E_(iib) AlkLE_(vii) E_(a) 1456 E_(1b)E₅E_(ii)E_(iib) AlkLE_(vii) E_(a) 1457 E_(1a)E₄ AlkLE_(vii) E_(a) 1458 E_(1b)E₄ AlkLE_(vii) E_(a) 1459 E_(1a)E₅E₄ AlkLE_(vii) E_(a) 1460 E_(1b)E₅E₄ AlkLE_(vii) E_(a) 1461 E_(1a)E_(i)E₄ AlkLE_(vii) E_(a) 1462 E_(1b)E_(i)E₄ AlkLE_(vii) E_(a) 1463 E_(1a)E_(ii)E₄ AlkLE_(vii) E_(a) 1464 E_(1b)E_(ii)E₄ AlkLE_(vii) E_(a) 1465 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(vii) E_(a) 1466 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(vii) E_(a) 1467 E_(1a)E₅E_(i)E₄ AlkLE_(vii) E_(a) 1468 E_(1b)E₅E_(i)E₄ AlkLE_(vii) E_(a) 1469 E_(1a)E₅E_(ii)E₄ AlkLE_(vii) E_(a) 1470 E_(1b)E₅E_(ii)E₄ AlkLE_(vii) E_(a) 1471 E_(1a)E₅E_(ii)E_(iib)E₄ AlkLE_(vii) E_(a) 1472 E_(1b)E₅E_(ii)E_(iib)E₄ AlkLE_(vii) E_(a) 1473 E_(1a)E_(iii) AlkLE_(vii) E_(a) 1474 E_(1b)E_(iii) AlkLE_(vii) E_(a) 1475 E_(1a)E₅E_(iii) AlkLE_(vii) E_(a) 1476 E_(1b)E₅E_(iii) AlkLE_(vii) E_(a) 1477 E_(1a)E_(iii)E₄ AlkLE_(vii) E_(a) 1478 E_(1b)E_(iii)E₄ AlkLE_(vii) E_(a) 1479 E_(1a)E₅E_(iii)E₄ AlkLE_(vii) E_(a) 1480 E_(1b)E₅E_(iii)E₄ AlkLE_(vii) E_(a) 1481 E_(1a)E_(iv) AlkLE_(vii) E_(a) 1482 E_(1b)E_(iv) AlkLE_(vii) E_(a) 1483 E_(1a)E₅E_(iv) AlkLE_(vii) E_(a) 1484 E_(1b)E₅E_(iv) AlkLE_(vii) E_(a) 1485 E_(1a)E_(iv)E₄ AlkLE_(vii) E_(a) 1486 E_(1b)E_(iv)E₄ AlkLE_(vii) E_(a) 1487 E_(1a)E₅E_(iv)E₄ AlkLE_(vii) E_(a) 1488 E_(1b)E₅E_(iv)E₄ AlkLE_(vii) E_(a) 1489 E_(1a) AlkLE_(vii) E₄* E_(a) 1490 E_(1b) AlkLE_(vii) E₄* E_(a) 1491 E_(1a)E₅ AlkLE_(vii) E₄* E_(a) 1492 E_(1b)E₅ AlkLE_(vii) E₄* E_(a) 1493 E_(1a)E_(i) AlkLE_(vii) E₄* E_(a) 1494 E_(1b)E_(i) AlkLE_(vii) E₄* E_(a) 1495 E_(1a)E_(ii) AlkLE_(vii) E₄* E_(a) 1496 E_(1b)E_(ii) AlkLE_(vii) E₄* E_(a) 1497 E_(1a)E_(ii)E_(iib) AlkLE_(vii) E₄* E_(a) 1498 E_(1b)E_(ii)E_(iib) AlkLE_(vii) E₄* E_(a) 1499 E_(1a)E₅E_(i) AlkLE_(vii) E₄* E_(a) 1500 E_(1b)E₅E_(i) AlkLE_(vii) E₄* E_(a) 1501 E_(1a)E₅E_(ii) AlkLE_(vii) E₄* E_(a) 1502 E_(1b)E₅E_(ii) AlkLE_(vii) E₄* E_(a) 1503 E_(1a)E₅E_(ii)E_(iib) AlkLE_(vii) E₄* E_(a) 1504 E_(1b)E₅E_(ii)E_(iib) AlkLE_(vii) E₄* E_(a) 1505 E_(1a)E₄ AlkLE_(vii) E₄* E_(a) 1506 E_(1b)E₄ AlkLE_(vii) E₄* E_(a) 1507 E_(1a)E₅E₄ AlkLE_(vii) E₄* E_(a) 1508 E_(1b)E₅E₄ AlkLE_(vii) E₄* E_(a) 1509 E_(1a)E_(i)E₄ AlkLE_(vii) E₄* E_(a) 1510 E_(1b)E_(i)E₄ AlkLE_(vii) E₄* E_(a) 1511 E_(1a)E_(ii)E₄ AlkLE_(vii) E₄* E_(a) 1512 E_(1b)E_(ii)E₄ AlkLE_(vii) E₄* E_(a) 1513 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* E_(a) 1514 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* E_(a) 1515 E_(1a)E₅E_(i)E₄ AlkLE_(vii) E₄* E_(a) 1516 E_(1b)E₅E_(i)E₄ AlkLE_(vii) E₄* E_(a) 1517 E_(1a)E₅E_(ii)E₄ AlkLE_(vii) E₄* E_(a) 1518 E_(1b)E₅E_(ii)E₄ AlkLE_(vii) E₄* E_(a) 1519 E_(1a)E₅E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* E_(a) 1520 E_(1b)E₅E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* E_(a) 1521 E_(1a)E_(iii) AlkLE_(vii) E₄* E_(a) 1522 E_(1b)E_(iii) AlkLE_(vii) E₄* E_(a) 1523 E_(1a)E₅E_(iii) AlkLE_(vii) E₄* E_(a) 1524 E_(1b)E₅E_(iii) AlkLE_(vii) E₄* E_(a) 1525 E_(1a)E_(iii)E₄ AlkLE_(vii) E₄* E_(a) 1526 E_(1b)E_(iii)E₄ AlkLE_(vii) E₄* E_(a) 1527 E_(1a)E₅E_(iii)E₄ AlkLE_(vii) E₄* E_(a) 1528 E_(1b)E₅E_(iii)E₄ AlkLE_(vii) E₄* E_(a) 1529 E_(1a)E_(iv) AlkLE_(vii) E₄* E_(a) 1530 E_(1b)E_(iv) AlkLE_(vii) E₄* E_(a) 1531 E_(1a)E₅E_(iv) AlkLE_(vii) E₄* E_(a) 1532 E_(1b)E₅E_(iv) AlkLE_(vii) E₄* E_(a) 1533 E_(1a)E_(iv)E₄ AlkLE_(vii) E₄* E_(a) 1534 E_(1b)E_(iv)E₄ AlkLE_(vii) E₄* E_(a) 1535 E_(1a)E₅E_(iv)E₄ AlkLE_(vii) E₄* E_(a) 1536 E_(1b)E₅E_(iv)E₄ AlkLE_(vii) E₄* E_(a) 1537 E_(1a) E_(vii) E_(b) 1538 E_(1b) E_(vii) E_(b) 1539 E_(1a)E₅ E_(vii) E_(b) 1540 E_(1b)E₅ E_(vii) E_(b) 1541 E_(1a)E_(i) E_(vii) E_(b) 1542 E_(1b)E_(i) E_(vii) E_(b) 1543 E_(1a)E_(ii) E_(vii) E_(b) 1544 E_(1b)E_(ii) E_(vii) E_(b) 1545 E_(1a)E_(ii)E_(iib) E_(vii) E_(b) 1546 E_(1b)E_(ii)E_(iib) E_(vii) E_(b) 1547 E_(1a)E₅E_(i) E_(vii) E_(b) 1548 E_(1b)E₅E_(i) E_(vii) E_(b) 1549 E_(1a)E₅E_(ii) E_(vii) E_(b) 1550 E_(1b)E₅E_(ii) E_(vii) E_(b) 1551 E_(1a)E₅E_(ii)E_(iib) E_(vii) E_(b) 1552 E_(1b)E₅E_(ii)E_(iib) E_(vii) E_(b) 1553 E_(1a)E₄ E_(vii) E_(b) 1554 E_(1b)E₄ E_(vii) E_(b) 1555 E_(1a)E₅E₄ E_(vii) E_(b) 1556 E_(1b)E₅E₄ E_(vii) E_(b) 1557 E_(1a)E_(i)E₄ E_(vii) E_(b) 1558 E_(1b)E_(i)E₄ E_(vii) E_(b) 1559 E_(1a)E_(ii)E₄ E_(vii) E_(b) 1560 E_(1b)E_(ii)E₄ E_(vii) E_(b) 1561 E_(1a)E_(ii)E_(iib)E₄ E_(vii) E_(b) 1562 E_(1b)E_(ii)E_(iib)E₄ E_(vii) E_(b) 1563 E_(1a)E₅E_(i)E₄ E_(vii) E_(b) 1564 E_(1b)E₅E_(i)E₄ E_(vii) E_(b) 1565 E_(1a)E₅E_(ii)E₄ E_(vii) E_(b) 1566 E_(1b)E₅E_(ii)E₄ E_(vii) E_(b) 1567 E_(1a)E₅E_(ii)E_(iib)E₄ E_(vii) E_(b) 1568 E_(1b)E₅E_(ii)E_(iib)E₄ E_(vii) E_(b) 1569 E_(1a)E_(iii) E_(vii) E_(b) 1570 E_(1b)E_(iii) E_(vii) E_(b) 1571 E_(1a)E₅E_(iii) E_(vii) E_(b) 1572 E_(1b)E₅E_(iii) E_(vii) E_(b) 1573 E_(1a)E_(iii)E₄ E_(vii) E_(b) 1574 E_(1b)E_(iii)E₄ E_(vii) E_(b) 1575 E_(1a)E₅E_(iii)E₄ E_(vii) E_(b) 1576 E_(1b)E₅E_(iii)E₄ E_(vii) E_(b) 1577 E_(1a)E_(iv) E_(vii) E_(b) 1578 E_(1b)E_(iv) E_(vii) E_(b) 1579 E_(1a)E₅E_(iv) E_(vii) E_(b) 1580 E_(1b)E₅E_(iv) E_(vii) E_(b) 1581 E_(1a)E_(iv)E₄ E_(vii) E_(b) 1582 E_(1b)E_(iv)E₄ E_(vii) E_(b) 1583 E_(1a)E₅E_(iv)E₄ E_(vii) E_(b) 1584 E_(1b)E₅E_(iv)E₄ E_(vii) E_(b) 1585 E_(1a) E_(vii) E₄* E_(b) 1586 E_(1b) E_(vii) E₄* E_(b) 1587 E_(1a)E₅ E_(vii) E₄* E_(b) 1588 E_(1b)E₅ E_(vii) E₄* E_(b) 1589 E_(1a)E_(i) E_(vii) E₄* E_(b) 1590 E_(1b)E_(i) E_(vii) E₄* E_(b) 1591 E_(1a)E_(ii) E_(vii) E₄* E_(b) 1592 E_(1b)E_(ii) E_(vii) E₄* E_(b) 1593 E_(1a)E_(ii)E_(iib) E_(vii) E₄* E_(b) 1594 E_(1b)E_(ii)E_(iib) E_(vii) E₄* E_(b) 1595 E_(1a)E₅E_(i) E_(vii) E₄* E_(b) 1596 E_(1b)E₅E_(i) E_(vii) E₄* E_(b) 1597 E_(1a)E₅E_(ii) E_(vii) E₄* E_(b) 1598 E_(1b)E₅E_(ii) E_(vii) E₄* E_(b) 1599 E_(1a)E₅E_(ii)E_(iib) E_(vii) E₄* E_(b) 1600 E_(1b)E₅E_(ii)E_(iib) E_(vii) E₄* E_(b) 1601 E_(1a)E₄ E_(vii) E₄* E_(b) 1602 E_(1b)E₄ E_(vii) E₄* E_(b) 1603 E_(1a)E₅E₄ E_(vii) E₄* E_(b) 1604 E_(1b)E₅E₄ E_(vii) E₄* E_(b) 1605 E_(1a)E_(i)E₄ E_(vii) E₄* E_(b) 1606 E_(1b)E_(i)E₄ E_(vii) E₄* E_(b) 1607 E_(1a)E_(ii)E₄ E_(vii) E₄* E_(b) 1608 E_(1b)E_(ii)E₄ E_(vii) E₄* E_(b) 1609 E_(1a)E_(ii)E_(iib)E₄ E_(vii) E₄* E_(b) 1610 E_(1b)E_(ii)E_(iib)E₄ E_(vii) E₄* E_(b) 1611 E_(1a)E₅E_(i)E₄ E_(vii) E₄* E_(b) 1612 E_(1b)E₅E_(i)E₄ E_(vii) E₄* E_(b) 1613 E_(1a)E₅E_(ii)E₄ E_(vii) E₄* E_(b) 1614 E_(1b)E₅E_(ii)E₄ E_(vii) E₄* E_(b) 1615 E_(1a)E₅E_(ii)E_(iib)E₄ E_(vii) E₄* E_(b) 1616 E_(1b)E₅E_(ii)E_(iib)E₄ E_(vii) E₄* E_(b) 1617 E_(1a)E_(iii) E_(vii) E₄* E_(b) 1618 E_(1b)E_(iii) E_(vii) E₄* E_(b) 1619 E_(1a)E₅E_(iii) E_(vii) E₄* E_(b) 1620 E_(1b)E₅E_(iii) E_(vii) E₄* E_(b) 1621 E_(1a)E_(iii)E₄ E_(vii) E₄* E_(b) 1622 E_(1b)E_(iii)E₄ E_(vii) E₄* E_(b) 1623 E_(1a)E₅E_(iii)E₄ E_(vii) E₄* E_(b) 1624 E_(1b)E₅E_(iii)E₄ E_(vii) E₄* E_(b) 1625 E_(1a)E_(iv) E_(vii) E₄* E_(b) 1626 E_(1b)E_(iv) E_(vii) E₄* E_(b) 1627 E_(1a)E₅E_(iv) E_(vii) E₄* E_(b) 1628 E_(1b)E₅E_(iv) E_(vii) E₄* E_(b) 1629 E_(1a)E_(iv)E₄ E_(vii) E₄* E_(b) 1630 E_(1b)E_(iv)E₄ E_(vii) E₄* E_(b) 1631 E_(1a)E₅E_(iv)E₄ E_(vii) E₄* E_(b) 1632 E_(1b)E₅E_(iv)E₄ E_(vii) E₄* E_(b) 1633 E_(1a) AlkLE_(vii) E_(b) 1634 E_(1b) AlkLE_(vii) E_(b) 1635 E_(1a)E₅ AlkLE_(vii) E_(b) 1636 E_(1b)E₅ AlkLE_(vii) E_(b) 1637 E_(1a)E_(i) AlkLE_(vii) E_(b) 1638 E_(1b)E_(i) AlkLE_(vii) E_(b) 1639 E_(1a)E_(ii) AlkLE_(vii) E_(b) 1640 E_(1b)E_(ii) AlkLE_(vii) E_(b) 1641 E_(1a)E_(ii)E_(iib) AlkLE_(vii) E_(b) 1642 E_(1b)E_(ii)E_(iib) AlkLE_(vii) E_(b) 1643 E_(1a)E₅E_(i) AlkLE_(vii) E_(b) 1644 E_(1b)E₅E_(i) AlkLE_(vii) E_(b) 1645 E_(1a)E₅E_(ii) AlkLE_(vii) E_(b) 1646 E_(1b)E₅E_(ii) AlkLE_(vii) E_(b) 1647 E_(1a)E₅E_(ii)E_(iib) AlkLE_(vii) E_(b) 1648 E_(1b)E₅E_(ii)E_(iib) AlkLE_(vii) E_(b) 1649 E_(1a)E₄ AlkLE_(vii) E_(b) 1650 E_(1b)E₄ AlkLE_(vii) E_(b) 1651 E_(1a)E₅E₄ AlkLE_(vii) E_(b) 1652 E_(1b)E₅E₄ AlkLE_(vii) E_(b) 1653 E_(1a)E_(i)E₄ AlkLE_(vii) E_(b) 1654 E_(1b)E_(i)E₄ AlkLE_(vii) E_(b) 1655 E_(1a)E_(ii)E₄ AlkLE_(vii) E_(b) 1656 E_(1b)E_(ii)E₄ AlkLE_(vii) E_(b) 1657 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(vii) E_(b) 1658 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(vii) E_(b) 1659 E_(1a)E₅E_(i)E₄ AlkLE_(vii) E_(b) 1660 E_(1b)E₅E_(i)E₄ AlkLE_(vii) E_(b) 1661 E_(1a)E₅E_(ii)E₄ AlkLE_(vii) E_(b) 1662 E_(1b)E₅E_(ii)E₄ AlkLE_(vii) E_(b) 1663 E_(1a)E₅E_(ii)E_(iib)E₄ AlkLE_(vii) E_(b) 1664 E_(1b)E₅E_(ii)E_(iib)E₄ AlkLE_(vii) E_(b) 1665 E_(1a)E_(iii) AlkLE_(vii) E_(b) 1666 E_(1b)E_(iii) AlkLE_(vii) E_(b) 1667 E_(1a)E₅E_(iii) AlkLE_(vii) E_(b) 1668 E_(1b)E₅E_(iii) AlkLE_(vii) E_(b) 1669 E_(1a)E_(iii)E₄ AlkLE_(vii) E_(b) 1670 E_(1b)E_(iii)E₄ AlkLE_(vii) E_(b) 1671 E_(1a)E₅E_(iii)E₄ AlkLE_(vii) E_(b) 1672 E_(1b)E₅E_(iii)E₄ AlkLE_(vii) E_(b) 1673 E_(1a)E_(iv) AlkLE_(vii) E_(b) 1674 E_(1b)E_(iv) AlkLE_(vii) E_(b) 1675 E_(1a)E₅E_(iv) AlkLE_(vii) E_(b) 1676 E_(1b)E₅E_(iv) AlkLE_(vii) E_(b) 1677 E_(1a)E_(iv)E₄ AlkLE_(vii) E_(b) 1678 E_(1b)E_(iv)E₄ AlkLE_(vii) E_(b) 1679 E_(1a)E₅E_(iv)E₄ AlkLE_(vii) E_(b) 1680 E_(1b)E₅E_(iv)E₄ AlkLE_(vii) E_(b) 1681 E_(1a) AlkLE_(vii) E₄* E_(b) 1682 E_(1b) AlkLE_(vii) E₄* E_(b) 1683 E_(1a)E₅ AlkLE_(vii) E₄* E_(b) 1684 E_(1b)E₅ AlkLE_(vii) E₄* E_(b) 1685 E_(1a)E_(i) AlkLE_(vii) E₄* E_(b) 1686 E_(1b)E_(i) AlkLE_(vii) E₄* E_(b) 1687 E_(1a)E_(ii) AlkLE_(vii) E₄* E_(b) 1688 E_(1b)E_(ii) AlkLE_(vii) E₄* E_(b) 1689 E_(1a)E_(ii)E_(iib) AlkLE_(vii) E₄* E_(b) 1690 E_(1b)E_(ii)E_(iib) AlkLE_(vii) E₄* E_(b) 1691 E_(1a)E₅E_(i) AlkLE_(vii) E₄* E_(b) 1692 E_(1b)E₅E_(i) AlkLE_(vii) E₄* E_(b) 1693 E_(1a)E₅E_(ii) AlkLE_(vii) E₄* E_(b) 1694 E_(1b)E₅E_(ii) AlkLE_(vii) E₄* E_(b) 1695 E_(1a)E₅E_(ii)E_(iib) AlkLE_(vii) E₄* E_(b) 1696 E_(1b)E₅E_(ii)E_(iib) AlkLE_(vii) E₄* E_(b) 1697 E_(1a)E₄ AlkLE_(vii) E₄* E_(b) 1698 E_(1b)E₄ AlkLE_(vii) E₄* E_(b) 1699 E_(1a)E₅E₄ AlkLE_(vii) E₄* E_(b) 1700 E_(1b)E₅E₄ AlkLE_(vii) E₄* E_(b) 1701 E_(1a)E_(i)E₄ AlkLE_(vii) E₄* E_(b) 1702 E_(1b)E_(i)E₄ AlkLE_(vii) E₄* E_(b) 1703 E_(1a)E_(ii)E₄ AlkLE_(vii) E₄* E_(b) 1704 E_(1b)E_(ii)E₄ AlkLE_(vii) E₄* E_(b) 1705 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* E_(b) 1706 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* E_(b) 1707 E_(1a)E₅E_(i)E₄ AlkLE_(vii) E₄* E_(b) 1708 E_(1b)E₅E_(i)E₄ AlkLE_(vii) E₄* E_(b) 1709 E_(1a)E₅E_(ii)E₄ AlkLE_(vii) E₄* E_(b) 1710 E_(1b)E₅E_(ii)E₄ AlkLE_(vii) E₄* E_(b) 1711 E_(1a)E₅E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* E_(b) 1712 E_(1b)E₅E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* E_(b) 1713 E_(1a)E_(iii) AlkLE_(vii) E₄* E_(b) 1714 E_(1b)E_(iii) AlkLE_(vii) E₄* E_(b) 1715 E_(1a)E₅E_(iii) AlkLE_(vii) E₄* E_(b) 1716 E_(1b)E₅E_(iii) AlkLE_(vii) E₄* E_(b) 1717 E_(1a)E_(iii)E₄ AlkLE_(vii) E₄* E_(b) 1718 E_(1b)E_(iii)E₄ AlkLE_(vii) E₄* E_(b) 1719 E_(1a)E₅E_(iii)E₄ AlkLE_(vii) E₄* E_(b) 1720 E_(1b)E₅E_(iii)E₄ AlkLE_(vii) E₄* E_(b) 1721 E_(1a)E_(iv) AlkLE_(vii) E₄* E_(b) 1722 E_(1b)E_(iv) AlkLE_(vii) E₄* E_(b) 1723 E_(1a)E₅E_(iv) AlkLE_(vii) E₄* E_(b) 1724 E_(1b)E₅E_(iv) AlkLE_(vii) E₄* E_(b) 1725 E_(1a)E_(iv)E₄ AlkLE_(vii) E₄* E_(b) 1726 E_(1b)E_(iv)E₄ AlkLE_(vii) E₄* E_(b) 1727 E_(1a)E₅E_(iv)E₄ AlkLE_(vii) E₄* E_(b) 1728 E_(1b)E₅E_(iv)E₄ AlkLE_(vii) E₄* E_(b) 1729 E_(1a) E_(vii) E_(d) 1730 E_(1b) E_(vii) E_(d) 1731 E_(1a)E₅ E_(vii) E_(d) 1732 E_(1b)E₅ E_(vii) E_(d) 1733 E_(1a)E_(i) E_(vii) E_(d) 1734 E_(1b)E_(i) E_(vii) E_(d) 1735 E_(1a)E_(ii) E_(vii) E_(d) 1736 E_(1b)E_(ii) E_(vii) E_(d) 1737 E_(1a)E_(ii)E_(iib) E_(vii) E_(d) 1738 E_(1b)E_(ii)E_(iib) E_(vii) E_(d) 1739 E_(1a)E₅E_(i) E_(vii) E_(d) 1740 E_(1b)E₅E_(i) E_(vii) E_(d) 1741 E_(1a)E₅E_(ii) E_(vii) E_(d) 1742 E_(1b)E₅E_(ii) E_(vii) E_(d) 1743 E_(1a)E₅E_(ii)E_(iib) E_(vii) E_(d) 1744 E_(1b)E₅E_(ii)E_(iib) E_(vii) E_(d) 1745 E_(1a)E₄ E_(vii) E_(d) 1746 E_(1b)E₄ E_(vii) E_(d) 1747 E_(1a)E₅E₄ E_(vii) E_(d) 1748 E_(1b)E₅E₄ E_(vii) E_(d) 1749 E_(1a)E_(i)E₄ E_(vii) E_(d) 1750 E_(1b)E_(i)E₄ E_(vii) E_(d) 1751 E_(1a)E_(ii)E₄ E_(vii) E_(d) 1752 E_(1b)E_(ii)E₄ E_(vii) E_(d) 1753 E_(1a)E_(ii)E_(iib)E₄ E_(vii) E_(d) 1754 E_(1b)E_(ii)E_(iib)E₄ E_(vii) E_(d) 1755 E_(1a)E₅E_(i)E₄ E_(vii) E_(d) 1756 E_(1b)E₅E_(i)E₄ E_(vii) E_(d) 1757 E_(1a)E₅E_(ii)E₄ E_(vii) E_(d) 1758 E_(1b)E₅E_(ii)E₄ E_(vii) E_(d) 1759 E_(1a)E₅E_(ii)E_(iib)E₄ E_(vii) E_(d) 1760 E_(1b)E₅E_(ii)E_(iib)E₄ E_(vii) E_(d) 1761 E_(1a)E_(iii) E_(vii) E_(d) 1762 E_(1b)E_(iii) E_(vii) E_(d) 1763 E_(1a)E₅E_(iii) E_(vii) E_(d) 1764 E_(1b)E₅E_(iii) E_(vii) E_(d) 1765 E_(1a)E_(iii)E₄ E_(vii) E_(d) 1766 E_(1b)E_(iii)E₄ E_(vii) E_(d) 1767 E_(1a)E₅E_(iii)E₄ E_(vii) E_(d) 1768 E_(1b)E₅E_(iii)E₄ E_(vii) E_(d) 1769 E_(1a)E_(iv) E_(vii) E_(d) 1770 E_(1b)E_(iv) E_(vii) E_(d) 1771 E_(1a)E₅E_(iv) E_(vii) E_(d) 1772 E_(1b)E₅E_(iv) E_(vii) E_(d) 1773 E_(1a)E_(iv)E₄ E_(vii) E_(d) 1774 E_(1b)E_(iv)E₄ E_(vii) E_(d) 1775 E_(1a)E₅E_(iv)E₄ E_(vii) E_(d) 1776 E_(1b)E₅E_(iv)E₄ E_(vii) E_(d) 1777 E_(1a) E_(vii) E₄* E_(d) 1778 E_(1b) E_(vii) E₄* E_(d) 1779 E_(1a)E₅ E_(vii) E₄* E_(d) 1780 E_(1b)E₅ E_(vii) E₄* E_(d) 1781 E_(1a)E_(i) E_(vii) E₄* E_(d) 1782 E_(1b)E_(i) E_(vii) E₄* E_(d) 1783 E_(1a)E_(ii) E_(vii) E₄* E_(d) 1784 E_(1b)E_(ii) E_(vii) E₄* E_(d) 1785 E_(1a)E_(ii)E_(iib) E_(vii) E₄* E_(d) 1786 E_(1b)E_(ii)E_(iib) E_(vii) E₄* E_(d) 1787 E_(1a)E₅E_(i) E_(vii) E₄* E_(d) 1788 E_(1b)E₅E_(i) E_(vii) E₄* E_(d) 1789 E_(1a)E₅E_(ii) E_(vii) E₄* E_(d) 1790 E_(1b)E₅E_(ii) E_(vii) E₄* E_(d) 1791 E_(1a)E₅E_(ii)E_(iib) E_(vii) E₄* E_(d) 1792 E_(1b)E₅E_(ii)E_(iib) E_(vii) E₄* E_(d) 1793 E_(1a)E₄ E_(vii) E₄* E_(d) 1794 E_(1b)E₄ E_(vii) E₄* E_(d) 1795 E_(1a)E₅E₄ E_(vii) E₄* E_(d) 1796 E_(1b)E₅E₄ E_(vii) E₄* E_(d) 1797 E_(1a)E_(i)E₄ E_(vii) E₄* E_(d) 1798 E_(1b)E_(i)E₄ E_(vii) E₄* E_(d) 1799 E_(1a)E_(ii)E₄ E_(vii) E₄* E_(d) 1800 E_(1b)E_(ii)E₄ E_(vii) E₄* E_(d) 1801 E_(1a)E_(ii)E_(iib)E₄ E_(vii) E₄* E_(d) 1802 E_(1b)E_(ii)E_(iib)E₄ E_(vii) E₄* E_(d) 1803 E_(1a)E₅E_(i)E₄ E_(vii) E₄* E_(d) 1804 E_(1b)E₅E_(i)E₄ E_(vii) E₄* E_(d) 1805 E_(1a)E₅E_(ii)E₄ E_(vii) E₄* E_(d) 1806 E_(1b)E₅E_(ii)E₄ E_(vii) E₄* E_(d) 1807 E_(1a)E₅E_(ii)E_(iib)E₄ E_(vii) E₄* E_(d) 1808 E_(1b)E₅E_(ii)E_(iib)E₄ E_(vii) E₄* E_(d) 1809 E_(1a)E_(iii) E_(vii) E₄* E_(d) 1810 E_(1b)E_(iii) E_(vii) E₄* E_(d) 1811 E_(1a)E₅E_(iii) E_(vii) E₄* E_(d) 1812 E_(1b)E₅E_(iii) E_(vii) E₄* E_(d) 1813 E_(1a)E_(iii)E₄ E_(vii) E₄* E_(d) 1814 E_(1b)E_(iii)E₄ E_(vii) E₄* E_(d) 1815 E_(1a)E₅E_(iii)E₄ E_(vii) E₄* E_(d) 1816 E_(1b)E₅E_(iii)E₄ E_(vii) E₄* E_(d) 1817 E_(1a)E_(iv) E_(vii) E₄* E_(d) 1818 E_(1b)E_(iv) E_(vii) E₄* E_(d) 1819 E_(1a)E₅E_(iv) E_(vii) E₄* E_(d) 1820 E_(1b)E₅E_(iv) E_(vii) E₄* E_(d) 1821 E_(1a)E_(iv)E₄ E_(vii) E₄* E_(d) 1822 E_(1b)E_(iv)E₄ E_(vii) E₄* E_(d) 1823 E_(1a)E₅E_(iv)E₄ E_(vii) E₄* E_(d) 1824 E_(1b)E₅E_(iv)E₄ E_(vii) E₄* E_(d) 1825 E_(1a) AlkLE_(vii) E_(d) 1826 E_(1b) AlkLE_(vii) E_(d) 1827 E_(1a)E₅ AlkLE_(vii) E_(d) 1828 E_(1b)E₅ AlkLE_(vii) E_(d) 1829 E_(1a)E_(i) AlkLE_(vii) E_(d) 1830 E_(1b)E_(i) AlkLE_(vii) E_(d) 1831 E_(1a)E_(ii) AlkLE_(vii) E_(d) 1832 E_(1b)E_(ii) AlkLE_(vii) E_(d) 1833 E_(1a)E_(ii)E_(iib) AlkLE_(vii) E_(d) 1834 E_(1b)E_(ii)E_(iib) AlkLE_(vii) E_(d) 1835 E_(1a)E₅E_(i) AlkLE_(vii) E_(d) 1836 E_(1b)E₅E_(i) AlkLE_(vii) E_(d) 1837 E_(1a)E₅E_(ii) AlkLE_(vii) E_(d) 1838 E_(1b)E₅E_(ii) AlkLE_(vii) E_(d) 1839 E_(1a)E₅E_(ii)E_(iib) AlkLE_(vii) E_(d) 1840 E_(1b)E₅E_(ii)E_(iib) AlkLE_(vii) E_(d) 1841 E_(1a)E₄ AlkLE_(vii) E_(d) 1842 E_(1b)E₄ AlkLE_(vii) E_(d) 1843 E_(1a)E₅E₄ AlkLE_(vii) E_(d) 1844 E_(1b)E₅E₄ AlkLE_(vii) E_(d) 1845 E_(1a)E_(i)E₄ AlkLE_(vii) E_(d) 1846 E_(1b)E_(i)E₄ AlkLE_(vii) E_(d) 1847 E_(1a)E_(ii)E₄ AlkLE_(vii) E_(d) 1848 E_(1b)E_(ii)E₄ AlkLE_(vii) E_(d) 1849 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(vii) E_(d) 1850 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(vii) E_(d) 1851 E_(1a)E₅E_(i)E₄ AlkLE_(vii) E_(d) 1852 E_(1b)E₅E_(i)E₄ AlkLE_(vii) E_(d) 1853 E_(1a)E₅E_(ii)E₄ AlkLE_(vii) E_(d) 1854 E_(1b)E₅E_(ii)E₄ AlkLE_(vii) E_(d) 1855 E_(1a)E₅E_(ii)E_(iib)E₄ AlkLE_(vii) E_(d) 1856 E_(1b)E₅E_(ii)E_(iib)E₄ AlkLE_(vii) E_(d) 1857 E_(1a)E_(iii) AlkLE_(vii) E_(d) 1858 E_(1b)E_(iii) AlkLE_(vii) E_(d) 1859 E_(1a)E₅E_(iii) AlkLE_(vii) E_(d) 1860 E_(1b)E₅E_(iii) AlkLE_(vii) E_(d) 1861 E_(1a)E_(iii)E₄ AlkLE_(vii) E_(d) 1862 E_(1b)E_(iii)E₄ AlkLE_(vii) E_(d) 1863 E_(1a)E₅E_(iii)E₄ AlkLE_(vii) E_(d) 1864 E_(1b)E₅E_(iii)E₄ AlkLE_(vii) E_(d) 1865 E_(1a)E_(iv) AlkLE_(vii) E_(d) 1866 E_(1b)E_(iv) AlkLE_(vii) E_(d) 1867 E_(1a)E₅E_(iv) AlkLE_(vii) E_(d) 1868 E_(1b)E₅E_(iv) AlkLE_(vii) E_(d) 1869 E_(1a)E_(iv)E₄ AlkLE_(vii) E_(d) 1870 E_(1b)E_(iv)E₄ AlkLE_(vii) E_(d) 1871 E_(1a)E₅E_(iv)E₄ AlkLE_(vii) E_(d) 1872 E_(1b)E₅E_(iv)E₄ AlkLE_(vii) E_(d) 1873 E_(1a) AlkLE_(vii) E₄* E_(d) 1874 E_(1b) AlkLE_(vii) E₄* E_(d) 1875 E_(1a)E₅ AlkLE_(vii) E₄* E_(d) 1876 E_(1b)E₅ AlkLE_(vii) E₄* E_(d) 1877 E_(1a)E_(i) AlkLE_(vii) E₄* E_(d) 1878 E_(1b)E_(i) AlkLE_(vii) E₄* E_(d) 1879 E_(1a)E_(ii) AlkLE_(vii) E₄* E_(d) 1880 E_(1b)E_(ii) AlkLE_(vii) E₄* E_(d) 1881 E_(1a)E_(ii)E_(iib) AlkLE_(vii) E₄* E_(d) 1882 E_(1b)E_(ii)E_(iib) AlkLE_(vii) E₄* E_(d) 1883 E_(1a)E₅E_(i) AlkLE_(vii) E₄* E_(d) 1884 E_(1b)E₅E_(i) AlkLE_(vii) E₄* E_(d) 1885 E_(1a)E₅E_(ii) AlkLE_(vii) E₄* E_(d) 1886 E_(1b)E₅E_(ii) AlkLE_(vii) E₄* E_(d) 1887 E_(1a)E₅E_(ii)E_(iib) AlkLE_(vii) E₄* E_(d) 1888 E_(1b)E₅E_(ii)E_(iib) AlkLE_(vii) E₄* E_(d) 1889 E_(1a)E₄ AlkLE_(vii) E₄* E_(d) 1890 E_(1b)E₄ AlkLE_(vii) E₄* E_(d) 1891 E_(1a)E₅E₄ AlkLE_(vii) E₄* E_(d) 1892 E_(1b)E₅E₄ AlkLE_(vii) E₄* E_(d) 1893 E_(1a)E_(i)E₄ AlkLE_(vii) E₄* E_(d) 1894 E_(1b)E_(i)E₄ AlkLE_(vii) E₄* E_(d) 1895 E_(1a)E_(ii)E₄ AlkLE_(vii) E₄* E_(d) 1896 E_(1b)E_(ii)E₄ AlkLE_(vii) E₄* E_(d) 1897 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* E_(d) 1898 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* E_(d) 1899 E_(1a)E₅E_(i)E₄ AlkLE_(vii) E₄* E_(d) 1900 E_(1b)E₅E_(i)E₄ AlkLE_(vii) E₄* E_(d) 1901 E_(1a)E₅E_(ii)E₄ AlkLE_(vii) E₄* E_(d) 1902 E_(1b)E₅E_(ii)E₄ AlkLE_(vii) E₄* E_(d) 1903 E_(1a)E₅E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* E_(d) 1904 E_(1b)E₅E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* E_(d) 1905 E_(1a)E_(iii) AlkLE_(vii) E₄* E_(d) 1906 E_(1b)E_(iii) AlkLE_(vii) E₄* E_(d) 1907 E_(1a)E₅E_(iii) AlkLE_(vii) E₄* E_(d) 1908 E_(1b)E₅E_(iii) AlkLE_(vii) E₄* E_(d) 1909 E_(1a)E_(iii)E₄ AlkLE_(vii) E₄* E_(d) 1910 E_(1b)E_(iii)E₄ AlkLE_(vii) E₄* E_(d) 1911 E_(1a)E₅E_(iii)E₄ AlkLE_(vii) E₄* E_(d) 1912 E_(1b)E₅E_(iii)E₄ AlkLE_(vii) E₄* E_(d) 1913 E_(1a)E_(iv) AlkLE_(vii) E₄* E_(d) 1914 E_(1b)E_(iv) AlkLE_(vii) E₄* E_(d) 1915 E_(1a)E₅E_(iv) AlkLE_(vii) E₄* E_(d) 1916 E_(1b)E₅E_(iv) AlkLE_(vii) E₄* E_(d) 1917 E_(1a)E_(iv)E₄ AlkLE_(vii) E₄* E_(d) 1918 E_(1b)E_(iv)E₄ AlkLE_(vii) E₄* E_(d) 1919 E_(1a)E₅E_(iv)E₄ AlkLE_(vii) E₄* E_(d) 1920 E_(1b)E₅E_(iv)E₄ AlkLE_(vii) E₄* E_(d) 1921 E_(1a) E_(vii) E_(e) 1922 E_(1b) E_(vii) E_(e) 1923 E_(1a)E₅ E_(vii) E_(e) 1924 E_(1b)E₅ E_(vii) E_(e) 1925 E_(1a)E_(i) E_(vii) E_(e) 1926 E_(1b)E_(i) E_(vii) E_(e) 1927 E_(1a)E_(ii) E_(vii) E_(e) 1928 E_(1b)E_(ii) E_(vii) E_(e) 1929 E_(1a)E_(ii)E_(iib) E_(vii) E_(e) 1930 E_(1b)E_(ii)E_(iib) E_(vii) E_(e) 1931 E_(1a)E₅E_(i) E_(vii) E_(e) 1932 E_(1b)E₅E_(i) E_(vii) E_(e) 1933 E_(1a)E₅E_(ii) E_(vii) E_(e) 1934 E_(1b)E₅E_(ii) E_(vii) E_(e) 1935 E_(1a)E₅E_(ii)E_(iib) E_(vii) E_(e) 1936 E_(1b)E₅E_(ii)E_(iib) E_(vii) E_(e) 1937 E_(1a)E₄ E_(vii) E_(e) 1938 E_(1b)E₄ E_(vii) E_(e) 1939 E_(1a)E₅E₄ E_(vii) E_(e) 1940 E_(1b)E₅E₄ E_(vii) E_(e) 1941 E_(1a)E_(i)E₄ E_(vii) E_(e) 1942 E_(1b)E_(i)E₄ E_(vii) E_(e) 1943 E_(1a)E_(ii)E₄ E_(vii) E_(e) 1944 E_(1b)E_(ii)E₄ E_(vii) E_(e) 1945 E_(1a)E_(ii)E_(iib)E₄ E_(vii) E_(e) 1946 E_(1b)E_(ii)E_(iib)E₄ E_(vii) E_(e) 1947 E_(1a)E₅E_(i)E₄ E_(vii) E_(e) 1948 E_(1b)E₅E_(i)E₄ E_(vii) E_(e) 1949 E_(1a)E₅E_(ii)E₄ E_(vii) E_(e) 1950 E_(1b)E₅E_(ii)E₄ E_(vii) E_(e) 1951 E_(1a)E₅E_(ii)E_(iib)E₄ E_(vii) E_(e) 1952 E_(1b)E₅E_(ii)E_(iib)E₄ E_(vii) E_(e) 1953 E_(1a)E_(iii) E_(vii) E_(e) 1954 E_(1b)E_(iii) E_(vii) E_(e) 1955 E_(1a)E₅E_(iii) E_(vii) E_(e) 1956 E_(1b)E₅E_(iii) E_(vii) E_(e) 1957 E_(1a)E_(iii)E₄ E_(vii) E_(e) 1958 E_(1b)E_(iii)E₄ E_(vii) E_(e) 1959 E_(1a)E₅E_(iii)E₄ E_(vii) E_(e) 1960 E_(1b)E₅E_(iii)E₄ E_(vii) E_(e) 1961 E_(1a)E_(iv) E_(vii) E_(e) 1962 E_(1b)E_(iv) E_(vii) E_(e) 1963 E_(1a)E₅E_(iv) E_(vii) E_(e) 1964 E_(1b)E₅E_(iv) E_(vii) E_(e) 1965 E_(1a)E_(iv)E₄ E_(vii) E_(e) 1966 E_(1b)E_(iv)E₄ E_(vii) E_(e) 1967 E_(1a)E₅E_(iv)E₄ E_(vii) E_(e) 1968 E_(1b)E₅E_(iv)E₄ E_(vii) E_(e) 1969 E_(1a) E_(vii) E₄* E_(e) 1970 E_(1b) E_(vii) E₄* E_(e) 1971 E_(1a)E₅ E_(vii) E₄* E_(e) 1972 E_(1b)E₅ E_(vii) E₄* E_(e) 1973 E_(1a)E_(i) E_(vii) E₄* E_(e) 1974 E_(1b)E_(i) E_(vii) E₄* E_(e) 1975 E_(1a)E_(ii) E_(vii) E₄* E_(e) 1976 E_(1b)E_(ii) E_(vii) E₄* E_(e) 1977 E_(1a)E_(ii)E_(iib) E_(vii) E₄* E_(e) 1978 E_(1b)E_(ii)E_(iib) E_(vii) E₄* E_(e) 1979 E_(1a)E₅E_(i) E_(vii) E₄* E_(e) 1980 E_(1b)E₅E_(i) E_(vii) E₄* E_(e) 1981 E_(1a)E₅E_(ii) E_(vii) E₄* E_(e) 1982 E_(1b)E₅E_(ii) E_(vii) E₄* E_(e) 1983 E_(1a)E₅E_(ii)E_(iib) E_(vii) E₄* E_(e) 1984 E_(1b)E₅E_(ii)E_(iib) E_(vii) E₄* E_(e) 1985 E_(1a)E₄ E_(vii) E₄* E_(e) 1986 E_(1b)E₄ E_(vii) E₄* E_(e) 1987 E_(1a)E₅E₄ E_(vii) E₄* E_(e) 1988 E_(1b)E₅E₄ E_(vii) E₄* E_(e) 1989 E_(1a)E_(i)E₄ E_(vii) E₄* E_(e) 1990 E_(1b)E_(i)E₄ E_(vii) E₄* E_(e) 1991 E_(1a)E_(ii)E₄ E_(vii) E₄* E_(e) 1992 E_(1b)E_(ii)E₄ E_(vii) E₄* E_(e) 1993 E_(1a)E_(ii)E_(iib)E₄ E_(vii) E₄* E_(e) 1994 E_(1b)E_(ii)E_(iib)E₄ E_(vii) E₄* E_(e) 1995 E_(1a)E₅E_(i)E₄ E_(vii) E₄* E_(e) 1996 E_(1b)E₅E_(i)E₄ E_(vii) E₄* E_(e) 1997 E_(1a)E₅E_(ii)E₄ E_(vii) E₄* E_(e) 1998 E_(1b)E₅E_(ii)E₄ E_(vii) E₄* E_(e) 1999 E_(1a)E₅E_(ii)E_(iib)E₄ E_(vii) E₄* E_(e) 2000 E_(1b)E₅E_(ii)E_(iib)E₄ E_(vii) E₄* E_(e) 2001 E_(1a)E_(iii) E_(vii) E₄* E_(e) 2002 E_(1b)E_(iii) E_(vii) E₄* E_(e) 2003 E_(1a)E₅E_(iii) E_(vii) E₄* E_(e) 2004 E_(1b)E₅E_(iii) E_(vii) E₄* E_(e) 2005 E_(1a)E_(iii)E₄ E_(vii) E₄* E_(e) 2006 E_(1b)E_(iii)E₄ E_(vii) E₄* E_(e) 2007 E_(1a)E₅E_(iii)E₄ E_(vii) E₄* E_(e) 2008 E_(1b)E₅E_(iii)E₄ E_(vii) E₄* E_(e) 2009 E_(1a)E_(iv) E_(vii) E₄* E_(e) 2010 E_(1b)E_(iv) E_(vii) E₄* E_(e) 2011 E_(1a)E₅E_(iv) E_(vii) E₄* E_(e) 2012 E_(1b)E₅E_(iv) E_(vii) E₄* E_(e) 2013 E_(1a)E_(iv)E₄ E_(vii) E₄* E_(e) 2014 E_(1b)E_(iv)E₄ E_(vii) E₄* E_(e) 2015 E_(1a)E₅E_(iv)E₄ E_(vii) E₄* E_(e) 2016 E_(1b)E₅E_(iv)E₄ E_(vii) E₄* E_(e) 2017 E_(1a) AlkLE_(vii) E_(e) 2018 E_(1b) AlkLE_(vii) E_(e) 2019 E_(1a)E₅ AlkLE_(vii) E_(e) 2020 E_(1b)E₅ AlkLE_(vii) E_(e) 2021 E_(1a)E_(i) AlkLE_(vii) E_(e) 2022 E_(1b)E_(i) AlkLE_(vii) E_(e) 2023 E_(1a)E_(ii) AlkLE_(vii) E_(e) 2024 E_(1b)E_(ii) AlkLE_(vii) E_(e) 2025 E_(1a)E_(ii)E_(iib) AlkLE_(vii) E_(e) 2026 E_(1b)E_(ii)E_(iib) AlkLE_(vii) E_(e) 2027 E_(1a)E₅E_(i) AlkLE_(vii) E_(e) 2028 E_(1b)E₅E_(i) AlkLE_(vii) E_(e) 2029 E_(1a)E₅E_(ii) AlkLE_(vii) E_(e) 2030 E_(1b)E₅E_(ii) AlkLE_(vii) E_(e) 2031 E_(1a)E₅E_(ii)E_(iib) AlkLE_(vii) E_(e) 2032 E_(1b)E₅E_(ii)E_(iib) AlkLE_(vii) E_(e) 2033 E_(1a)E₄ AlkLE_(vii) E_(e) 2034 E_(1b)E₄ AlkLE_(vii) E_(e) 2035 E_(1a)E₅E₄ AlkLE_(vii) E_(e) 2036 E_(1b)E₅E₄ AlkLE_(vii) E_(e) 2037 E_(1a)E_(i)E₄ AlkLE_(vii) E_(e) 2038 E_(1b)E_(i)E₄ AlkLE_(vii) E_(e) 2039 E_(1a)E_(ii)E₄ AlkLE_(vii) E_(e) 2040 E_(1b)E_(ii)E₄ AlkLE_(vii) E_(e) 2041 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(vii) E_(e) 2042 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(vii) E_(e) 2043 E_(1a)E₅E_(i)E₄ AlkLE_(vii) E_(e) 2044 E_(1b)E₅E_(i)E₄ AlkLE_(vii) E_(e) 2045 E_(1a)E₅E_(ii)E₄ AlkLE_(vii) E_(e) 2046 E_(1b)E₅E_(ii)E₄ AlkLE_(vii) E_(e) 2047 E_(1a)E₅E_(ii)E_(iib)E₄ AlkLE_(vii) E_(e) 2048 E_(1b)E₅E_(ii)E_(iib)E₄ AlkLE_(vii) E_(e) 2049 E_(1a)E_(iii) AlkLE_(vii) E_(e) 2050 E_(1b)E_(iii) AlkLE_(vii) E_(e) 2051 E_(1a)E₅E_(iii) AlkLE_(vii) E_(e) 2052 E_(1b)E₅E_(iii) AlkLE_(vii) E_(e) 2053 E_(1a)E_(iii)E₄ AlkLE_(vii) E_(e) 2054 E_(1b)E_(iii)E₄ AlkLE_(vii) E_(e) 2055 E_(1a)E₅E_(iii)E₄ AlkLE_(vii) E_(e) 2056 E_(1b)E₅E_(iii)E₄ AlkLE_(vii) E_(e) 2057 E_(1a)E_(iv) AlkLE_(vii) E_(e) 2058 E_(1b)E_(iv) AlkLE_(vii) E_(e) 2059 E_(1a)E₅E_(iv) AlkLE_(vii) E_(e) 2060 E_(1b)E₅E_(iv) AlkLE_(vii) E_(e) 2061 E_(1a)E_(iv)E₄ AlkLE_(vii) E_(e) 2062 E_(1b)E_(iv)E₄ AlkLE_(vii) E_(e) 2063 E_(1a)E₅E_(iv)E₄ AlkLE_(vii) E_(e) 2064 E_(1b)E₅E_(iv)E₄ AlkLE_(vii) E_(e) 2065 E_(1a) AlkLE_(vii) E₄* E_(e) 2066 E_(1b) AlkLE_(vii) E₄* E_(e) 2067 E_(1a)E₅ AlkLE_(vii) E₄* E_(e) 2068 E_(1b)E₅ AlkLE_(vii) E₄* E_(e) 2069 E_(1a)E_(i) AlkLE_(vii) E₄* E_(e) 2070 E_(1b)E_(i) AlkLE_(vii) E₄* E_(e) 2071 E_(1a)E_(ii) AlkLE_(vii) E₄* E_(e) 2072 E_(1b)E_(ii) AlkLE_(vii) E₄* E_(e) 2073 E_(1a)E_(ii)E_(iib) AlkLE_(vii) E₄* E_(e) 2074 E_(1b)E_(ii)E_(iib) AlkLE_(vii) E₄* E_(e) 2075 E_(1a)E₅E_(i) AlkLE_(vii) E₄* E_(e) 2076 E_(1b)E₅E_(i) AlkLE_(vii) E₄* E_(e) 2077 E_(1a)E₅E_(ii) AlkLE_(vii) E₄* E_(e) 2078 E_(1b)E₅E_(ii) AlkLE_(vii) E₄* E_(e) 2079 E_(1a)E₅E_(ii)E_(iib) AlkLE_(vii) E₄* E_(e) 2080 E_(1b)E₅E_(ii)E_(iib) AlkLE_(vii) E₄* E_(e) 2081 E_(1a)E₄ AlkLE_(vii) E₄* E_(e) 2082 E_(1b)E₄ AlkLE_(vii) E₄* E_(e) 2083 E_(1a)E₅E₄ AlkLE_(vii) E₄* E_(e) 2084 E_(1b)E₅E₄ AlkLE_(vii) E₄* E_(e) 2085 E_(1a)E_(i)E₄ AlkLE_(vii) E₄* E_(e) 2086 E_(1b)E_(i)E₄ AlkLE_(vii) E₄* E_(e) 2087 E_(1a)E_(ii)E₄ AlkLE_(vii) E₄* E_(e) 2088 E_(1b)E_(ii)E₄ AlkLE_(vii) E₄* E_(e) 2089 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* E_(e) 2090 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* E_(e) 2091 E_(1a)E₅E_(i)E₄ AlkLE_(vii) E₄* E_(e) 2092 E_(1b)E₅E_(i)E₄ AlkLE_(vii) E₄* E_(e) 2093 E_(1a)E₅E_(ii)E₄ AlkLE_(vii) E₄* E_(e) 2094 E_(1b)E₅E_(ii)E₄ AlkLE_(vii) E₄* E_(e) 2095 E_(1a)E₅E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* E_(e) 2096 E_(1b)E₅E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* E_(e) 2097 E_(1a)E_(iii) AlkLE_(vii) E₄* E_(e) 2098 E_(1b)E_(iii) AlkLE_(vii) E₄* E_(e) 2099 E_(1a)E₅E_(iii) AlkLE_(vii) E₄* E_(e) 2100 E_(1b)E₅E_(iii) AlkLE_(vii) E₄* E_(e) 2101 E_(1a)E_(iii)E₄ AlkLE_(vii) E₄* E_(e) 2102 E_(1b)E_(iii)E₄ AlkLE_(vii) E₄* E_(e) 2103 E_(1a)E₅E_(iii)E₄ AlkLE_(vii) E₄* E_(e) 2104 E_(1b)E₅E_(iii)E₄ AlkLE_(vii) E₄* E_(e) 2105 E_(1a)E_(iv) AlkLE_(vii) E₄* E_(e) 2106 E_(1b)E_(iv) AlkLE_(vii) E₄* E_(e) 2107 E_(1a)E₅E_(iv) AlkLE_(vii) E₄* E_(e) 2108 E_(1b)E₅E_(iv) AlkLE_(vii) E₄* E_(e) 2109 E_(1a)E_(iv)E₄ AlkLE_(vii) E₄* E_(e) 2110 E_(1b)E_(iv)E₄ AlkLE_(vii) E₄* E_(e) 2111 E_(1a)E₅E_(iv)E₄ AlkLE_(vii) E₄* E_(e) 2112 E_(1b)E₅E_(iv)E₄ AlkLE_(vii) E₄* E_(e) 2113 E_(1a) E_(vii) E_(f) 2114 E_(1b) E_(vii) E_(f) 2115 E_(1a)E₅ E_(vii) E_(f) 2116 E_(1b)E₅ E_(vii) E_(f) 2117 E_(1a)E_(i) E_(vii) E_(f) 2118 E_(1b)E_(i) E_(vii) E_(f) 2119 E_(1a)E_(ii) E_(vii) E_(f) 2120 E_(1b)E_(ii) E_(vii) E_(f) 2121 E_(1a)E_(ii)E_(iib) E_(vii) E_(f) 2122 E_(1b)E_(ii)E_(iib) E_(vii) E_(f) 2123 E_(1a)E₅E_(i) E_(vii) E_(f) 2124 E_(1b)E₅E_(i) E_(vii) E_(f) 2125 E_(1a)E₅E_(ii) E_(vii) E_(f) 2126 E_(1b)E₅E_(ii) E_(vii) E_(f) 2127 E_(1a)E₅E_(ii)E_(iib) E_(vii) E_(f) 2128 E_(1b)E₅E_(ii)E_(iib) E_(vii) E_(f) 2129 E_(1a)E₄ E_(vii) E_(f) 2130 E_(1b)E₄ E_(vii) E_(f) 2131 E_(1a)E₅E₄ E_(vii) E_(f) 2132 E_(1b)E₅E₄ E_(vii) E_(f) 2133 E_(1a)E_(i)E₄ E_(vii) E_(f) 2134 E_(1b)E_(i)E₄ E_(vii) E_(f) 2135 E_(1a)E_(ii)E₄ E_(vii) E_(f) 2136 E_(1b)E_(ii)E₄ E_(vii) E_(f) 2137 E_(1a)E_(ii)E_(iib)E₄ E_(vii) E_(f) 2138 E_(1b)E_(ii)E_(iib)E₄ E_(vii) E_(f) 2139 E_(1a)E₅E_(i)E₄ E_(vii) E_(f) 2140 E_(1b)E₅E_(i)E₄ E_(vii) E_(f) 2141 E_(1a)E₅E_(ii)E₄ E_(vii) E_(f) 2142 E_(1b)E₅E_(ii)E₄ E_(vii) E_(f) 2143 E_(1a)E₅E_(ii)E_(iib)E₄ E_(vii) E_(f) 2144 E_(1b)E₅E_(ii)E_(iib)E₄ E_(vii) E_(f) 2145 E_(1a)E_(iii) E_(vii) E_(f) 2146 E_(1b)E_(iii) E_(vii) E_(f) 2147 E_(1a)E₅E_(iii) E_(vii) E_(f) 2148 E_(1b)E₅E_(iii) E_(vii) E_(f) 2149 E_(1a)E_(iii)E₄ E_(vii) E_(f) 2150 E_(1b)E_(iii)E₄ E_(vii) E_(f) 2151 E_(1a)E₅E_(iii)E₄ E_(vii) E_(f) 2152 E_(1b)E₅E_(iii)E₄ E_(vii) E_(f) 2153 E_(1a)E_(iv) E_(vii) E_(f) 2154 E_(1b)E_(iv) E_(vii) E_(f) 2155 E_(1a)E₅E_(iv) E_(vii) E_(f) 2156 E_(1b)E₅E_(iv) E_(vii) E_(f) 2157 E_(1a)E_(iv)E₄ E_(vii) E_(f) 2158 E_(1b)E_(iv)E₄ E_(vii) E_(f) 2159 E_(1a)E₅E_(iv)E₄ E_(vii) E_(f) 2160 E_(1b)E₅E_(iv)E₄ E_(vii) E_(f) 2161 E_(1a) E_(vii) E₄* E_(f) 2162 E_(1b) E_(vii) E₄* E_(f) 2163 E_(1a)E₅ E_(vii) E₄* E_(f) 2164 E_(1b)E₅ E_(vii) E₄* E_(f) 2165 E_(1a)E_(i) E_(vii) E₄* E_(f) 2166 E_(1b)E_(i) E_(vii) E₄* E_(f) 2167 E_(1a)E_(ii) E_(vii) E₄* E_(f) 2168 E_(1b)E_(ii) E_(vii) E₄* E_(f) 2169 E_(1a)E_(ii)E_(iib) E_(vii) E₄* E_(f) 2170 E_(1b)E_(ii)E_(iib) E_(vii) E₄* E_(f) 2171 E_(1a)E₅E_(i) E_(vii) E₄* E_(f) 2172 E_(1b)E₅E_(i) E_(vii) E₄* E_(f) 2173 E_(1a)E₅E_(ii) E_(vii) E₄* E_(f) 2174 E_(1b)E₅E_(ii) E_(vii) E₄* E_(f) 2175 E_(1a)E₅E_(ii)E_(iib) E_(vii) E₄* E_(f) 2176 E_(1b)E₅E_(ii)E_(iib) E_(vii) E₄* E_(f) 2177 E_(1a)E₄ E_(vii) E₄* E_(f) 2178 E_(1b)E₄ E_(vii) E₄* E_(f) 2179 E_(1a)E₅E₄ E_(vii) E₄* E_(f) 2180 E_(1b)E₅E₄ E_(vii) E₄* E_(f) 2181 E_(1a)E_(i)E₄ E_(vii) E₄* E_(f) 2182 E_(1b)E_(i)E₄ E_(vii) E₄* E_(f) 2183 E_(1a)E_(ii)E₄ E_(vii) E₄* E_(f) 2184 E_(1b)E_(ii)E₄ E_(vii) E₄* E_(f) 2185 E_(1a)E_(ii)E_(iib)E₄ E_(vii) E₄* E_(f) 2186 E_(1b)E_(ii)E_(iib)E₄ E_(vii) E₄* E_(f) 2187 E_(1a)E₅E_(i)E₄ E_(vii) E₄* E_(f) 2188 E_(1b)E₅E_(i)E₄ E_(vii) E₄* E_(f) 2189 E_(1a)E₅E_(ii)E₄ E_(vii) E₄* E_(f) 2190 E_(1b)E₅E_(ii)E₄ E_(vii) E₄* E_(f) 2191 E_(1a)E₅E_(ii)E_(iib)E₄ E_(vii) E₄* E_(f) 2192 E_(1b)E₅E_(ii)E_(iib)E₄ E_(vii) E₄* E_(f) 2193 E_(1a)E_(iii) E_(vii) E₄* E_(f) 2194 E_(1b)E_(iii) E_(vii) E₄* E_(f) 2195 E_(1a)E₅E_(iii) E_(vii) E₄* E_(f) 2196 E_(1b)E₅E_(iii) E_(vii) E₄* E_(f) 2197 E_(1a)E_(iii)E₄ E_(vii) E₄* E_(f) 2198 E_(1b)E_(iii)E₄ E_(vii) E₄* E_(f) 2199 E_(1a)E₅E_(iii)E₄ E_(vii) E₄* E_(f) 2200 E_(1b)E₅E_(iii)E₄ E_(vii) E₄* E_(f) 2201 E_(1a)E_(iv) E_(vii) E₄* E_(f) 2202 E_(1b)E_(iv) E_(vii) E₄* E_(f) 2203 E_(1a)E₅E_(iv) E_(vii) E₄* E_(f) 2204 E_(1b)E₅E_(iv) E_(vii) E₄* E_(f) 2205 E_(1a)E_(iv)E₄ E_(vii) E₄* E_(f) 2206 E_(1b)E_(iv)E₄ E_(vii) E₄* E_(f) 2207 E_(1a)E₅E_(iv)E₄ E_(vii) E₄* E_(f) 2208 E_(1b)E₅E_(iv)E₄ E_(vii) E₄* E_(f) 2209 E_(1a) AlkLE_(vii) E_(f) 2210 E_(1b) AlkLE_(vii) E_(f) 2211 E_(1a)E₅ AlkLE_(vii) E_(f) 2212 E_(1b)E₅ AlkLE_(vii) E_(f) 2213 E_(1a)E_(i) AlkLE_(vii) E_(f) 2214 E_(1b)E_(i) AlkLE_(vii) E_(f) 2215 E_(1a)E_(ii) AlkLE_(vii) E_(f) 2216 E_(1b)E_(ii) AlkLE_(vii) E_(f) 2217 E_(1a)E_(ii)E_(iib) AlkLE_(vii) E_(f) 2218 E_(1b)E_(ii)E_(iib) AlkLE_(vii) E_(f) 2219 E_(1a)E₅E_(i) AlkLE_(vii) E_(f) 2220 E_(1b)E₅E_(i) AlkLE_(vii) E_(f) 2221 E_(1a)E₅E_(ii) AlkLE_(vii) E_(f) 2222 E_(1b)E₅E_(ii) AlkLE_(vii) E_(f) 2223 E_(1a)E₅E_(ii)E_(iib) AlkLE_(vii) E_(f) 2224 E_(1b)E₅E_(ii)E_(iib) AlkLE_(vii) E_(f) 2225 E_(1a)E₄ AlkLE_(vii) E_(f) 2226 E_(1b)E₄ AlkLE_(vii) E_(f) 2227 E_(1a)E₅E₄ AlkLE_(vii) E_(f) 2228 E_(1b)E₅E₄ AlkLE_(vii) E_(f) 2229 E_(1a)E_(i)E₄ AlkLE_(vii) E_(f) 2230 E_(1b)E_(i)E₄ AlkLE_(vii) E_(f) 2231 E_(1a)E_(ii)E₄ AlkLE_(vii) E_(f) 2232 E_(1b)E_(ii)E₄ AlkLE_(vii) E_(f) 2233 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(vii) E_(f) 2234 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(vii) E_(f) 2235 E_(1a)E₅E_(i)E₄ AlkLE_(vii) E_(f) 2236 E_(1b)E₅E_(i)E₄ AlkLE_(vii) E_(f) 2237 E_(1a)E₅E_(ii)E₄ AlkLE_(vii) E_(f) 2238 E_(1b)E₅E_(ii)E₄ AlkLE_(vii) E_(f) 2239 E_(1a)E₅E_(ii)E_(iib)E₄ AlkLE_(vii) E_(f) 2240 E_(1b)E₅E_(ii)E_(iib)E₄ AlkLE_(vii) E_(f) 2241 E_(1a)E_(iii) AlkLE_(vii) E_(f) 2242 E_(1b)E_(iii) AlkLE_(vii) E_(f) 2243 E_(1a)E₅E_(iii) AlkLE_(vii) E_(f) 2244 E_(1b)E₅E_(iii) AlkLE_(vii) E_(f) 2245 E_(1a)E_(iii)E₄ AlkLE_(vii) E_(f) 2246 E_(1b)E_(iii)E₄ AlkLE_(vii) E_(f) 2247 E_(1a)E₅E_(iii)E₄ AlkLE_(vii) E_(f) 2248 E_(1b)E₅E_(iii)E₄ AlkLE_(vii) E_(f) 2249 E_(1a)E_(iv) AlkLE_(vii) E_(f) 2250 E_(1b)E_(iv) AlkLE_(vii) E_(f) 2251 E_(1a)E₅E_(iv) AlkLE_(vii) E_(f) 2252 E_(1b)E₅E_(iv) AlkLE_(vii) E_(f) 2253 E_(1a)E_(iv)E₄ AlkLE_(vii) E_(f) 2254 E_(1b)E_(iv)E₄ AlkLE_(vii) E_(f) 2255 E_(1a)E₅E_(iv)E₄ AlkLE_(vii) E_(f) 2256 E_(1b)E₅E_(iv)E₄ AlkLE_(vii) E_(f) 2257 E_(1a) AlkLE_(vii) E₄* E_(f) 2258 E_(1b) AlkLE_(vii) E₄* E_(f) 2259 E_(1a)E₅ AlkLE_(vii) E₄* E_(f) 2260 E_(1b)E₅ AlkLE_(vii) E₄* E_(f) 2261 E_(1a)E_(i) AlkLE_(vii) E₄* E_(f) 2262 E_(1b)E_(i) AlkLE_(vii) E₄* E_(f) 2263 E_(1a)E_(ii) AlkLE_(vii) E₄* E_(f) 2264 E_(1b)E_(ii) AlkLE_(vii) E₄* E_(f) 2265 E_(1a)E_(ii)E_(iib) AlkLE_(vii) E₄* E_(f) 2266 E_(1b)E_(ii)E_(iib) AlkLE_(vii) E₄* E_(f) 2267 E_(1a)E₅E_(i) AlkLE_(vii) E₄* E_(f) 2268 E_(1b)E₅E_(i) AlkLE_(vii) E₄* E_(f) 2269 E_(1a)E₅E_(ii) AlkLE_(vii) E₄* E_(f) 2270 E_(1b)E₅E_(ii) AlkLE_(vii) E₄* E_(f) 2271 E_(1a)E₅E_(ii)E_(iib) AlkLE_(vii) E₄* E_(f) 2272 E_(1b)E₅E_(ii)E_(iib) AlkLE_(vii) E₄* E_(f) 2273 E_(1a)E₄ AlkLE_(vii) E₄* E_(f) 2274 E_(1b)E₄ AlkLE_(vii) E₄* E_(f) 2275 E_(1a)E₅E₄ AlkLE_(vii) E₄* E_(f) 2276 E_(1b)E₅E₄ AlkLE_(vii) E₄* E_(f) 2277 E_(1a)E_(i)E₄ AlkLE_(vii) E₄* E_(f) 2278 E_(1b)E_(i)E₄ AlkLE_(vii) E₄* E_(f) 2279 E_(1a)E_(ii)E₄ AlkLE_(vii) E₄* E_(f) 2280 E_(1b)E_(ii)E₄ AlkLE_(vii) E₄* E_(f) 2281 E_(1a)E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* E_(f) 2282 E_(1b)E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* E_(f) 2283 E_(1a)E₅E_(i)E₄ AlkLE_(vii) E₄* E_(f) 2284 E_(1b)E₅E_(i)E₄ AlkLE_(vii) E₄* E_(f) 2285 E_(1a)E₅E_(ii)E₄ AlkLE_(vii) E₄* E_(f) 2286 E_(1b)E₅E_(ii)E₄ AlkLE_(vii) E₄* E_(f) 2287 E_(1a)E₅E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* E_(f) 2288 E_(1b)E₅E_(ii)E_(iib)E₄ AlkLE_(vii) E₄* E_(f) 2289 E_(1a)E_(iii) AlkLE_(vii) E₄* E_(f) 2290 E_(1b)E_(iii) AlkLE_(vii) E₄* E_(f) 2291 E_(1a)E₅E_(iii) AlkLE_(vii) E₄* E_(f) 2292 E_(1b)E₅E_(iii) AlkLE_(vii) E₄* E_(f) 2293 E_(1a)E_(iii)E₄ AlkLE_(vii) E₄* E_(f) 2294 E_(1b)E_(iii)E₄ AlkLE_(vii) E₄* E_(f) 2295 E_(1a)E₅E_(iii)E₄ AlkLE_(vii) E₄* E_(f) 2296 E_(1b)E₅E_(iii)E₄ AlkLE_(vii) E₄* E_(f) 2297 E_(1a)E_(iv) AlkLE_(vii) E₄* E_(f) 2298 E_(1b)E_(iv) AlkLE_(vii) E₄* E_(f) 2299 E_(1a)E₅E_(iv) AlkLE_(vii) E₄* E_(f) 2300 E_(1b)E₅E_(iv) AlkLE_(vii) E₄* E_(f) 2301 E_(1a)E_(iv)E₄ AlkLE_(vii) E₄* E_(f) 2302 E_(1b)E_(iv)E₄ AlkLE_(vii) E₄* E_(f) 2303 E_(1a)E₅E_(iv)E₄ AlkLE_(vii) E₄* E_(f) 2304 E_(1b)E₅E_(iv)E₄ AlkLE_(vii) E₄* E_(f)

Use of the Microorganisms According to the Invention

A further subject of the present invention relates to the use of the aforesaid microorganisms for the production of ω-functionalized carboxylic acids and ω-functionalized carboxylate esters, in particular of those carboxylic acids and carboxylate esters, which were emphasized above as preferable in connection with the microorganisms according to the invention, wherein as the ω-functionalization, ω-amination in particular is to be emphasized. The use of the aforesaid microorganisms for the production of ω-aminocarboxylic acids and ω-aminocarboxylate esters, in particular ω-aminolauric acid and methyl and ethyl ω-aminolaurates and ω-aminocaproic acid and methyl and ethyl ω-aminocaproates is particularly preferable.

Microorganisms emphasized as preferable in connection with the microorganisms according to the invention are also preferable in connection with the use according to the invention. Which organisms according to the invention are preferable for specific ω-functionalized carboxylic acids or ω-functionalized carboxylate esters has already been emphasized in connection with the microorganisms according to the invention.

Process for the Production of ω-Functionalized Carboxylic Acids and of ω-Functionalized carboxylate esters

A further subject of the present invention relates to a process for the production of ω-functionalized carboxylic acids and ω-functionalized carboxylate esters from a simple carbon source comprising the process steps

I) contacting a microorganism according to the invention with a medium containing the simple carbon source, II) culturing the microorganism under conditions which enable the microorganism to form the ω-functionalized carboxylic acids or ω-functionalized carboxylate esters from the simple carbon source and III) optionally isolation of the ω-functionalized carboxylic acids or ω-functionalized carboxylate esters formed.

In the process according to the invention, the microorganisms according to the invention can be contacted with the culture medium and cultured continuously or discontinuously in the batch process (batch culturing) or the fed-batch process or the repeated fed-batch process for the purpose of producing the ω-functionalized carboxylic acids or ω-functionalized carboxylate esters. Also possible is a semicontinuous process as described in GB-A-1009370. A summary of known culturing methods is described in the textbook by Chmiel (“Bioprozesstechnik 1. Einführung in die Bioverfahrenstechnik”, Gustav Fischer Verlag, Stuttgart, 1991) or in the textbook by Storhas (“Bioreaktoren and periphere Einrichtungen”, Vieweg Verlag, Braunschweig/Wiesbaden, 1994).

The culture medium to be used must appropriately meet the requirements of the respective strains. Descriptions of culture media for various microorganisms are contained in the American Society for Bacteriology manual “Manual of Methods for General Bacteriology” (Washington D.C., USA, 1981).

In the process according to the invention, microorganisms preferred according to the invention are preferably used.

As the simple carbon source in the process according to the invention, those mentioned above as preferable are used.

As the nitrogen source, organic nitrogen-containing compounds such as peptone, yeast extract, meat extract, malt extract, corn steep liquor, soya bean meal and urea or inorganic compounds such as ammonium sulphate, ammonium chloride, ammonium phosphate, ammonium carbonate and ammonium nitrate, ammonia, ammonium hydroxide or aqueous ammonia can be used. The nitrogen sources can be used singly or as a mixture.

As the phosphorus source, phosphoric acid, potassium dihydrogen phosphate or dipotassium hydrogen phosphate or the corresponding sodium-containing salts can be used. The culture medium must further contain salts of metals, such as for example magnesium sulphate or iron sulphate, which are necessary for growth. Finally, essential nutrients such as amino acids and vitamins can be used in addition to the abovementioned substances. Apart from this, suitable precursors can be added to the culture medium. The said additives can be added to the culture in the form of a single preparation or fed in during the culturing in a suitable manner.

For pH control of the culture, basic compounds such as sodium hydroxide, potassium hydroxide, ammonia or aqueous ammonia or acidic compounds such as phosphoric acid or sulphuric acid can be used in a suitable manner. To control foam development, antifoaming agents such as for example fatty acid polyglycol esters can be used. For maintenance of the stability of plasmids, suitable selectively acting substances such as for example antibiotics can be added to the media. In order to maintain aerobic conditions, oxygen or oxygen-containing gas mixtures such as for example air are introduced into the culture.

According to one embodiment of the process according to the invention, this is performed in a two-phase system, comprising

A) an aqueous phase, and B) an organic phase, wherein the formation of the ω-functionalized carboxylic acids or ω-functionalized carboxylate esters by the microorganism in process step II) takes place in the aqueous phase and the ω-functionalized carboxylic acids or ω-functionalized carboxylate esters formed accumulate in the organic phase. In this manner, it is possible to extract the ω-functionalized carboxylic acids or ω-functionalized carboxylate esters formed in situ.

Preferred ω-functionalized carboxylic acids or ω-functionalized carboxylate esters which are produced with the process according to the invention are those mentioned above as preferred in connection with the microorganisms according to the invention and the use according to the invention.

Especially preferred ω-functionalized carboxylic acids or ω-functionalized carboxylate esters are the

ω-aminocarboxylic acids and ω-aminocarboxylate esters, in particular ω-aminolauric acid and methyl and ethyl ω-aminolaurates and ω-aminocaproic acid and methyl and ethyl ω-aminocaproates, and ω-hydroxycarboxylic acids and ω-hydroxycarboxylate esters, in particular ω-hydroxylauric acid and methyl and ethyl ω-hydroxylaurates and ω-hydroxycaproic acid and methyl and ethyl ω-hydroxycaproates, and ω-carboxycarboxylic acids and ω-carboxycarboxylate esters, in particular ω-carboxylauric acid and methyl and ethyl ω-carboxylaurates, and ω-carboxycaproic acid and methyl and ethyl ω-carboxycaproates.

Which organisms according to the invention are preferably used in preferred processes according to the invention for specific ω-functionalized carboxylic acids or ω-functionalized carboxylate esters has already been emphasized in connection with the microorganisms according to the invention.

A further subject of the present invention is a process for the production of polyamides based on ω-aminocarboxylic acids, comprising the process steps:

(a1) Production of ω-aminocarboxylic acids or ω-aminocarboxylate esters by one of the processes described above for the production of ω-aminocarboxylic acids, in particular by the process described above for the production of ω-aminolauric acid, methyl ω-aminolaurate, ω-aminocaproic acid or methyl ω-aminocaproate and optionally conversion of the ω-aminocarboxylate esters into ω-aminocarboxylic acids; (a2) Polymerization of the ω-aminocarboxylic acid with obtention of a polyamide.

In process step (a2) of the process according to the invention for the production of polyamides based on ω-aminocarboxylic acids, the ω-aminocarboxylate esters can be converted into the ω-aminocarboxylic acids by any processes such as for example acid- or base-catalysed hydrolysis.

In process step (a2) of the process according to the invention for the production of polyamides based on ω-aminocarboxylic acids, the ω-aminocarboxylic acids obtained in process step (a1), in particular the ω-aminolauric acid obtained in process step (a1), is converted to a polyamide in a polymerization wherein optionally mixtures of various ω-aminocarboxylic acids can also be used, whereof at least a part of the ω-aminocarboxylic acids, preferably at least 50 wt. % based on all ω-aminocarboxylic acids used in the process, but optionally also all ω-aminocarboxylic acids were produced by the process according to the invention for the production of ω-aminocarboxylic acids.

The production of the polyamides from the ω-aminocarboxylic acids can be effected in processes known per se, as for example described in L. Notarbartolo, Ind. Plast. Mod. 10 (1958) 2, p. 44, JP 01-074224, JP 01-051433, JP63286428, JP58080324 or JP60179425.

In the examples presented below, the present invention is described by way of example, without it being intended that the invention, the scope of whose application appears from the whole description and claims, be limited to the embodiments mentioned in the examples.

EXAMPLES Example 1 Production of Expression Vectors for the Genes fatB2 from Cuphea palustris, Ald from Bacillus subtilis and Cv_(—)2025 from Chromobacterium violaceum

For the production of an E. coli expression vector for the genes fatB2 (SEQ ID No. 10) from Cuphea palustris (enzyme E_(i)), aid (SEQ ID No. 11) from Bacillus subtilis (enzyme E₃) and Cv_(—)2025 (SEQ ID No. 12) from Chromobacterium violaceum (enzyme E₂), these genes were successively cloned into the vector pJ294 (DNA2.0 Inc., Menlo Park, Calif., USA). The gene Cv_(—)2025 was synthesized together with a lacUV5 promoter and the gene ald from Bacillus sphaericus and simultaneously a cleavage site upstream of the promoter and a cleavage site downstream of the terminator were introduced. The synthesized DNA fragment P_(lacUV5)-. ald_Bsp_TA_C.v.(Ct) (SEQ ID No. 13) was digested with the restriction endonucleases PstI and XbaI and ligated into the correspondingly cleaved vector pJ294. The finished E. coli expression vector was designated as pJ294_alaD_Bsp_TA_C.v.(Ct).(SEQ ID No. 14). In this vector, the Bacillus sphaericus ald gene was replaced by the gene ald from Bacillus subtilis. The gene ald was amplified by PCR from chromosomal DNA of the strain Bacillus subtilis str. 168. The following oligonucleotides were used in this:

alaDH_pCR22_fw: 5′-ATGATCATAGGGGTTCCTAAAGAG-3′ (SEQ ID No. 15) alaDH_pCR22_rev: 5′-TTAAGCACCCGCCACAGATG-3′ (SEQ ID No. 16)

The following parameters were used for the PCR: 1×: initial denaturation, 98° C., 0:30 mins; 35×: denaturation, 98° C., 0:10 min, annealing, 65° C., 0:30 mins; elongation, 72° C., 0:20 mins; 1×: terminal elongation, 72° C., 10 min. For the amplification, the Phusion™ High-Fidelity Master Mix from New England Biolabs (Frankfurt) was used according to the manufacturer's recommendations. 50 μl of each PCR reaction were then separated on a 1% TAE agarose gel.

The PCR, agarose gel electrophoresis, ethidium bromide staining of the DNA and determination of the PCR fragment sizes were performed in the manner known to those skilled in the art. The PCR fragment exhibited the expected size of 1137 base-pairs and was purified from the PCR preparation with the Quick PCR Purification Kit from Qiagen (Hilden) according to the manufacturer's instructions. For the ligation of the PCR product with the vector, 5′-phosphates were attached to the PCR product by means of polynucleotide kinase (New England Biolabs, Frankfurt). For this, the manufacturer's recommendation was followed.

The vector was digested with the restriction endonucleases HindIII and NdeI, whereby the contained gene Bacillus sphaericus ald was removed. The restriction digestion mixture was separated on a 1% TAE agarose gel. Two bands, of sizes 5696 bp and 1124 bp could be identified. For the isolation of the vector-DNA from the agarose gel, the DNA band of 5696 bp was isolated from the gel with a scalpel and purified with the Quick Gel Extraction Kit from Qiagen (Hilden) according to the manufacturer's instructions. To create blunt ends, the 5′ overhangs of the purified vector DNA were filled in by means of the Klenow fragment of DNA polymerase I (New England Biolabs, Frankfurt). For this, the manufacturer's instructions were followed. The DNA fragment Bacillus subtilis ald with 5′ phosphate residues was ligated into the vector with blunt ends. The finished E. coli expression vector was designated as pJ294_alaDH_B.s._TA_C.v.(Ct) (SEQ ID No. 17).

For the production of the complete expression vector, the gene fatB2 from Cuphea palustris was codon-optimized for expression in Escherichia coli. The gene was synthesized together with a tac promoter (DNA 2.0; Menlo Park, Calif., USA) and simultaneously a cleavage site upstream of the promoter and a cleavage site downstream of the terminator were introduced.

The synthesized DNA fragment P_(tac)-CpFatB2 (SEQ ID No. 18) was digested with the restriction endonucleases BamHI and NotI and ligated into the correspondingly cleaved vector pJ294_alaDH_B.s._TA_C.v.(Ct) and the vector pJ294. The finished vectors were designated as pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CpFATB2] (SEQ ID No. 19) and pJ294[Ptac-CpFATB2_optEc] (SEQ ID No. 20).

Example 2 LC-ESI/MS²-Based Quantification of Products

The quantification of methyl laurate LSME, methyl ω-hydroxylaurate HLSME, methyl ω-oxolaurate OLSME, methyl ω-aminolaurate ALSME and methyl ω-carboxylaurate DDSME, ω-aminolauric acid ALS, ω-carboxylauric acid DDS, lauric acid LS, ω-hydroxylauric acid HLS and ω-oxolauric acid OLS in fermentation samples was effected by means of LC-ESI/MS² on the basis of an external calibration for all analytes and with use of the internal standard aminoundecanoic acid (AUD).

For this, the following instruments were used:

-   -   HPLC unit 1260 (Agilent; Böblingen) with autosampler (G1367E),         binary pump (G1312B) and column oven (G1316A)     -   Mass spectrometer TripelQuad 6410 (Agilent; Böblingen) with ESI         source     -   HPLC column: Kinetex C18, 100×2.1 mm, particle size: 2.6 μm,         pore size 100 Å (Phenomenex; Aschaffenburg)     -   Precolumn: KrudKatcher Ultra HPLC in-line filter; 0.5 μm filter         depth and 0.004 mm internal diameter (Phenomenex; Aschaffenburg)

The samples were prepared by pipetting 1900 μL of solvent (acetone/0.1 N HCl mixture=1:1) and 100 μL of sample into a 2 mL reaction vessel. The mixture was vortexed for ca. 10 seconds and then centrifuged at ca. 13,000 rpm for 5 mins. The clear supernatant was withdrawn with a pipette and analysed after appropriate dilution with diluent (80% (v/v) ACN, 20% bidest. H₂O (v/v), +0.1% formic acid). 100 μL of ISTD were pipetted into each 900 μL sample (10 μL with a sample volume of 90 μL).

The HPLC separation was effected with the aforementioned column and precolumn. The injection volume was 0.7 μL, the column temperature 50° C. and the flow rate 0.6 ml/min. The mobile phase consisted of eluent A (0.1% (v/v) aqueous formic acid) and eluent B (acetonitrile with 0.1% (v/v) formic acid). The following gradient profile was used

Time [mins] Eluent A [%] Eluent B [%] 0 77 23 0.3 77 23 0.4 40 60 2.5 40 60 2.6 2 98 5.5 2 98 5.6 77 23 9 77 23

The ESI-MS² analysis was effected in positive mode with the following ESI source parameters:

-   -   Gas temperature 280° C.     -   Gas flow rate 11 l/min     -   Nebulizer pressure 50 psi     -   Capillary voltage 4000 V

The detection and quantification of the individual compounds was effected with the following parameters, wherein in each case one product ion was used as Qualifier and one as Quantifier

Precursor Product Dwell Collision Analyte Ion Ion time energy DDSME 245.2 167.1 25 6 DDSME 245.2 149.1 50 8 HLSME 231.3 181.2 15 2 HLSME 231.3 163.2 25 5 DDS 231.2 213.2 50 0 DDS 231.2 149.1 25 9 ALSME 230.3 198.1 25 10 ALSME 230.3 163.2 15 10 OLSME 229.2 197.2 50 0 OLSME 229.2 161.1 25 5 HLS 217.2 181.2 35 0 HLS 217.2 163.1 20 4 OLS 215.2 161.2 25 0 OLS 215.2 95.2 60 13

Example 3 Production of Aminolauric Acid by an E. coli Strain with Deletion of the Gene fadE and Expression Vectors for the Genes fatB2 from Cuphea Palustris, Ald from Bacillus subtilis, and Cv_(—)2025 from Chromobacterium violaceum in Combination with an Expression Vector for the Genes alkB, alkG, alkT and alkL from the alk Operon of Pseudomonas putida

The host strain used E. coli JW5020-1 (CGSC, The coli genetic stock center, Yale University, New Haven, USA) is an E. coli BW25113 derivative which carries a deletion of the gene fadE (coding for enzyme E_(b)). The gene fadE was replaced by a kanamycin cassette. Before the provision of the strain with the expression vectors by means of a helper plasmid which codes for the Flp recombinase, this was removed in a manner known to those skilled in the art (see Datsenko K. A. and Wanner B. L. (2000) PNAS 97(12):6640-6645), resulting in the strain E. coli JW5020-1 Kan^(S). To create an E. coli strain with expression vectors for the genes fatB2 from Cuphea palustris (enzyme E_(i)), a/d from Bacillus subtilis (enzyme E₃), and Cv_(—)2025 from Chromobacterium violaceum (enzyme E₂) in combination with the expression vector pBT10_alkL (sequence and production: compare Example 1 of PCT/EP2011/053834 and the Seq ID No. 8 listed there) for the genes alkB (enzyme E_(1a)), alkG, alkT (auxiliary enzymes to enzyme E_(1b)) and alkL (coding for alkL gene product) from the alk operon of Pseudomonas putida GPo1, electrocompetent cells of E. coli JW5020-1 Kan^(S) were produced. This took place in a manner known to those skilled in the art. This was transformed with the plasmids pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CpFATB2] and pBT10_alkL and plated out onto LB agar plates containing ampicillin (100 μg/ml) and kanamycin (50 μg/ml). Transformants were checked for the presence of the correct plasmids by plasmid preparation and analytical restriction analysis. In this manner, the following strain was constructed: E. coli JW5020-1 Kan^(S) pBT10_alkL/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CpFATB2].

The strain was subjected to a fed-batch fermentation in order to analyse its capacity for the production of aminolauric acid from glucose. The strain to be tested was firstly grown from a glycerine culture as a preculture in M9 medium containing 100 μg/ml ampicillin and 50 μg/ml kanamycin at 37° C. overnight. The medium, consisting of 38 mM disodium hydrogen phosphate dihydrate, 22 mM potassium dihydrogen phosphate, 8.6 mM sodium chloride, 37 mM ammonium chloride, 1.5% (w/v) glucose, 2 mM magnesium sulphate heptahydrate (all substances from Merck, Darmstadt) and 0.5% (v/v) trace element solution, was adjusted to a pH of 7.4 with 25% ammonium hydroxide solution. The trace element solution added, consisting of 9.7 mM manganese(II) chloride tetrahydrate, 6.5 mM zinc sulphate heptahydrate, 2.5 mM sodium EDTA (Titriplex III), 4.9 mM boric acid, 1 mM sodium molybdate dihydrate, 32 mM calcium chloride dihydrate, 64 mM iron(II) sulphate heptahydrate and 0.9 mM copper(II) chloride dihydrate dissolved in 37% hydrochloric acid (all substances from Merck, Darmstadt) was sterile-filtered before addition to the M9 medium. The fermenter was inoculated with the preculture such that an optical density of 0.06 was reached. The culturing was effected at a pH of 6.8, regulated with 25% aqueous ammonia and 0.5 M sulphuric acid, an oxygen partial pressure of 20%, regulated via a stirrer speed of 800 rpm/min and air feed of 0.4 vvm/min at the start of the fermentation, and a temperature of 37° C. The glucose feed took place after consumption of the glucose present in the medium, at a feed rate of 5 g/l/hr based on the initial volume. At the start of the glucose feed after 9 hours fermentation, the temperature was adjusted to 30° C. The gene expression was induced 2 hours after the start of the glucose feed by addition of 1 mM isopropyl-β-D-thiogalactopyranoside and 0.025% dicyclopropyl ketone. The strain was cultured for a further 49 hours under constant conditions. During the culturing, 1 ml samples were withdrawn and the concentration of fatty acids and ω-functionalized fatty acids quantified by the method described in Example 2. The results are shown in the following table.

C_(lauric acid) C_(carboxylauric acid) C_(hydroxylauric acid) C_(aminolauric acid) [mg/l] [mg/l] [mg/l] [mg/l] 56.5 16.0 54.4 22.8

Production of ω-functionalized fatty acids with E. coli JW5020-1 Kan^(S) pBT10_alkL/pJ294[alaDH_Bs_TAcv(ct_Ptac-CpFATB2]. The concentrations of lauric acid and ω-carboxylauric acid, ω-hydroxylauric acid and ω-aminolauric acid after 60 hours fermentation are stated:

Example 4 Production of an E. coli Expression Vector for the Genes fadD from Escherichia coli and atfA from Acinetobacter sp. ADP1

For the production of the E. coli expression vector for the genes fadD (SEQ ID No. 21) from Escherichia coli (coding for enzyme E_(v)) and atfA with terminator (SEQ ID No. 22) from Acinetobacter sp. ADP1 (coding for enzyme E_(v)) under control of a tac promoter, these genes were amplified from chromosomal DNA of E. coli W3110 and Acinetobacter calcoaceticus ADP1 respectively by PCR with incorporation of homologous regions for the recombination cloning.

The synthetic tac promoter (SEQ ID No. 23) was amplified with ribosome binding site from a pJ294 derivative (DNA 2.0; Menlo Park, Calif., USA) with incorporation of homologous regions.

The preparation of the chromosomal DNA from E. coli W3110 and Acinetobacter calcoaceticus ADP1 was effected by means of DNeasy Blood & Tissue Kit (Qiagen, Hilden) according to the manufacturer's instructions. In the amplification of the genes fadD from E. coli and atfA from Acinetobacter sp. ADP1 with chromosomal DNA of E. coli W3110 and Acinetobacter calcoaceticus ADP1 respectively as matrix, and the amplification of the synthetic promoter P_(tac) from a pJ294 derivative the following oligonucleotides were used:

Ptac: 11- 5′-TTATGCGACTCCTGCGTTTAGGGAAAGAGCATTTG-3′ 001_fw: (SEQ ID No. 24) Ptac-rv: 5′-GTTAACATATGTTTTACCTCCTGTTAAACAAA-3′ (SEQ ID No. 25) fadD [E. coli]: fad D- 5′-TAAAACATATGTTAACGGCATGTATATCATTT-3′ fw: (SEQ ID No. 26) fadD-rv: 5′-TCTCCTCAGACTTAACGCTCAGGCTTTATTGT-3′ (SEQ ID No. 27) atfA [Acinetobacter sp. ADP1]: atfA-fw: 5′-GTTAAGTCTGAGGAGATCCACGCTATGCGCCC-3′ (SEQ ID No. 28) 11- 5′-CAATTGAGATCTGCCACGACTGCAATGGTTCATC-3′ 002_rv: (SEQ ID No. 29)

The following parameters were used for the PCR: 1×: initial denaturation, 103° C., 3:00 mins; 35×: denaturation, 98° C., 0:10 mins, annealing, 65° C., 0:15 min; elongation, 72° C., 0:45 mins; 1×: terminal elongation, 72° C., 10 mins. For the amplification, the Phusion™ High-Fidelity Master Mix from New England Biolabs (Frankfurt) was used according to the manufacturer's recommendations. 50 μl of each PCR reaction were then separated on a 1% TAE agarose gel. The PCR, agarose gel electrophoresis, ethidium bromide staining of the DNA and determination of the PCR fragment sizes were performed in the manner known to those skilled in the art.

In all cases, PCR fragments of the expected size could be amplified. These were: for the promoter region P_(tac) 607 bp, for fadD 1778 bp and for atfA 1540 bp.

For the isolation of the DNA from an agarose gel, the target DNA was isolated from the gel with a scalpel and purified with the Quick Gel Extraction Kit from Qiagen (Hilden) according to the manufacturer's instructions. The purified PCR products were recombined with the EcoNI/NdeI-cleaved vector pCDFDuet™-1 (71340-3, Merck, Darmstadt) by means of in vitro cloning with use of the Geneart Seamless Cloning and Assembly Kit from Invitrogen (Darmstadt). The use corresponded to the manufacturer's recommendations. pCDFDuet-1 is an E. coli vector which mediates a spectinomycin/streptomycin resistance in the organism and carries a CoIDF13 replication origin. The transformation of chemically competent E. coli DH5α cells (New England Biolabs, Frankfurt) was effected in a manner known to those skilled in the art.

The correctness of the plasmid was checked by a restriction analysis with XbaI. The authenticity of the inserted fragments was checked by DNA sequencing. The finished E. coli expression vector was designated as pCDF[fadD-atfA] (SEQ ID No. 30).

Example 5 Production of Methyl Aminolaurate and Ethyl Aminolaurate by an E. coli Strain with Deletion of the Gene fadE and Expression Vectors for the Genes fatB2 from Cuphea palustris, Ald from Bacillus subtilis, and Cv_(—)2025 from Chromobacterium violaceum in Combination with an Expression Vector for the Genes alkB, alkG, alkT and alkL from the Alk Operon of Pseudomonas putida and an Expression Vector for the Genes fadD from Escherichia coli and atfA from Acinetobacter sp. ADP1

To create an E. coli strain with expression vectors for the genes fatB2 from Cuphea palustris (coding for enzyme E_(i)), a/d from Bacillus subtilis (coding for enzyme E₃) and Cv_(—)2025 from Chromobacterium violaceum (coding for enzyme E₂) in combination with an expression vector for the genes alkB (coding for enzyme E_(1b)), alkG, alkT (coding for auxiliary enzymes to enzyme E_(1b)) and alkL (coding for alkL gene product) from the alk operon of Pseudomonas putida GPo1 and an expression vector for the genes fadD from Escherichia coli (coding for enzyme E_(vi)) and atfA from Acinetobacter sp. ADP1 (coding for enzyme E_(v)), electrocompetent cells of E. coli JW5020-1 Kan^(S) are produced. This takes place in a manner known to those skilled in the art. E. coli JW5020-1 Kan^(S) is a derivative of E. coli JW5020-1 (CGSC, The coli genetic stock center, Yale University, New Haven, USA), and this in turn is an E. coli BW25113 derivative which carries a deletion of the gene fadE (coding for enzyme E_(b)). The gene fadE was replaced by a kanamycin cassette. Before the provision of the strain with the expression vectors by means of a helper plasmid, which codes for the Flp recombinase, this was removed in a manner known to those skilled in the art (see Datsenko K. A. and Wanner B. L. (2000) PNAS 97(12):6640-6645), resulting in the strain E. coli JW5020-1 Kan^(S) . E. coli JW5020-1 Kan^(S) and E. coli W3110 ΔfadE (construction described in Example 8) are sequentially transformed with the plasmids pBT10_alkL, pCDF[fadD-atfA] and pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CpFATB2] and plated out onto LB agar plates containing kanamycin (50 μg/ml), spectinomycin (100 μg/ml) and ampicillin (100 μg/ml). Transformants are checked for the presence of the correct plasmids by plasmid preparation and analytical restriction analysis. In this manner, the following strains are constructed: E. coli JW5020-1 Kan^(S) pBT10_alkL/pCDF[fadD-atfA]/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CpFATB2] and E. coli W3110 ΔfadE pBT10_alkL/pCDF[fadD-affA]/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CpFATB2].

The strain is subjected to fed-batch fermentation in order to analyse its capacity for the production of methyl aminolaurate and ethyl aminolaurate from glucose. The strain to be tested is firstly grown from a glycerine culture as a preculture in M9 medium containing kanamycin (50 μg/ml), spectinomycin (100 μg/ml) and ampicillin (100 μg/ml) at 37° C. overnight. The medium, consisting of 38 mM disodium hydrogen phosphate dihydrate, 22 mM potassium dihydrogen phosphate, 8.6 mM sodium chloride, 37 mM ammonium chloride, 1.5% (w/v) glucose, 2 mM magnesium sulphate heptahydrate (all substances from Merck, Darmstadt) and 0.5% (v/v) trace element solution, is adjusted to a pH of 7.4 with 25% ammonium hydroxide solution. The trace element solution added, consisting of 9.7 mM manganese(II) chloride tetrahydrate, 6.5 mM zinc sulphate heptahydrate, 2.5 mM sodium EDTA (Titriplex III), 4.9 mM boric acid, 1 mM sodium molybdate dihydrate, 32 mM calcium chloride dihydrate, 64 mM iron(II) sulphate heptahydrate and 0.9 mM copper(II) chloride dihydrate dissolved in 37% hydrochloric acid (all substances from Merck, Darmstadt), is sterile-filtered before addition to the M9 medium. The fermenter is inoculated with the preculture such that an optical density of 0.2 is reached. The culturing is effected at a pH of 6.8, regulated with 25% aqueous ammonia and 0.5 M sulphuric acid, an oxygen partial pressure of 20%, regulated via the stirrer speed and the air feed, and a temperature of 37° C. The glucose feed is effected after consumption of the glucose present in the medium, at a feed rate of 5 g/l/hr based on the initial volume. At the start of the glucose feed, the temperature is adjusted to 30° C. Gene expression is induced 2 hours after the start of the glucose feed by addition of 1 mM isopropyl-β-D-thiogalactopyranoside and 0.025% dicyclopropyl ketone. Simultaneously with the induction, 2% (v/v) methanol or 2% (v/v) ethanol are added as methyl group donor or ethyl group donor for the fatty acid esterification.

The strain is cultured for at least a further 48 hours under constant conditions. During the culturing, 1 ml samples are withdrawn and the concentration of fatty acid methyl esters, fatty acid ethyl esters, ω-functionalized fatty acid methyl esters and ω-functionalized fatty acid ethyl esters quantified by the method described in Example 2. It is shown that the strains E. coli JW5020-1 Kan^(S) pBT10_alkL/pCDF[fadD-atfA]/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CpFATB2] and E. coli W3110 ΔfadE pBT10_alkL/pCDF[fadD-atfA]/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CpFATB2] are capable of forming methyl laurate, methyl ω-hydroxylaurate, methyl ω-oxolaurate, methyl ω-aminolaurate and methyl ω-carboxylaurate with addition of 2% (v/v) methanol and ethyl laurate, ethyl ω-hydroxylaurate, ethyl ω-oxolaurate, ethyl ω-aminolaurate and ethyl ω-carboxylaurate with addition of 2% (v/v) ethanol respectively.

Example 6 Production of Expression Vectors for the Genes synUcTE from Umbellularia californica, Ald from Bacillus subtilis and Cv_(—)2025 from Chromobacterium violaceum

For the production of an E. coli expression vector for the genes synUcTE (SEQ ID No. 31) from Umbellularia californica (coding for an enzyme E_(i)), aid (SEQ ID No. 33) from Bacillus subtilis (coding for an enzyme E₃) and Cv_(—)2025 (SEQ ID No. 35) from Chromobacterium violaceum (coding for an enzyme E₂), the gene synUcTE was codon-optimized for expression in Escherichia coli and synthesized together with a tac promoter (SEQ ID No. 37). During the synthesis, a cleavage site upstream of the promoter and a cleavage site downstream of the terminator were introduced. The synthesized DNA fragment P_(tac) synUcTE was digested with the restriction endonucleases BamHI and NotI and ligated into the correspondingly cleaved vector pJ294_alaDH_B.s._TA_C.v.(Ct) (SEQ ID No. 17) and the vector pJ294 (DNA2.0 Inc., Menlo Park, Calif., USA). The finished vectors were designated as pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE] (SEQ ID No. 38) and pJ294[Ptac-synUcTE] (SEQ ID No. 39).

Example 7 Production of Expression Vectors for the Genes fadD from Escherichia coli and Wax-dgaT from Acinetobacter sp. ADP1 and atfA1 from Alcanivorax borkumensis

For the production of expression vectors for the genes fadD (SEQ ID No. 21) from Escherichia coli and wax-dgaT (SEQ ID No. 42) (coding for an enzyme E_(v)) from Acinetobacter sp. ADP1 and atfA1 (SEQ ID No. 44) (coding for an enzyme E_(v)) from Alcanivorax borkumensis SK2 respectively, the genes wax-dgaT and atfA1 were codon-optimized for expression in Escherichia coli and synthesized in combination with the Gen fadD from E. coli (coding for an enzyme E_(vi)). The synthesized DNA fragments wax-dgaT_AsADP1-fadD_Ec (SEQ ID No. 46) and atfA1_Ab-fadD_Ec (SEQ ID No. 47) were amplified with incorporation of homologous regions for recombination cloning.

For the amplification of the fragment wax-dgaT_AsADP1-fadD_Ec the following oligonucleotides were used:

wax-dgaT_H1_fw: 5′-ACAGGAGGTAAAACATATGCGTCCTCTGCACCCG-3′ (SEQ ID No. 51) fadD_H2_rv: 5′-GTTTCTTTACCAGACTCGAGATTGTTTTCTCTTTAGTGGGCGTC-3′ (SEQ ID No. 52) For the amplification of the fragment atfALAb-fadD Ec the following oligonucleotides were used: affA_Abfw_kurz: 5′-ACAGGAGGTAAAACATATGAAAGCGCTGTCCC-3′ (SEQ ID No. 53) fadD_H2_rv_N: 5′-GTTTCTTTACCAGACTCGAGATIGTTTTCTCTTTAGTGGGC-3′ (SEQ ID No. 54)

The following parameters were used for the PCR: 1×: initial denaturation, 98° C., 0:30 mins; 35×: denaturation, 98° C., 0:10 min, annealing, 70° C., 0:20 mins; elongation, 72° C., 1 min; 1×: terminal elongation, 72° C., 10 min. For the amplification, the Phusion™ High-Fidelity Master Mix from New England Biolabs (Frankfurt) was used according to the manufacturer's recommendations. 50 μl of each PCR reaction were then separated on a 1% TAE agarose gel. The PCR, agarose gel electrophoresis, ethidium bromide staining of the DNA and determination of the PCR fragment sizes were performed in the manner known to those skilled in the art. In both cases, PCR fragments of the expected size could be amplified. These were 3192 base pairs for wax-dgaT_AsADP1-fadD_Ec and 3189 base pairs for atfA1_Ab-fadD_Ec. For the isolation of the DNA from the agarose gel, the target DNA was cut out from the gel with a scalpel and purified with the QiaQuick Gel extraction Kit according to the manufacturer's instructions (Qiagen, Hilden). The purified PCR products were cloned into a NdeI- and XhoI-cleaved pCDF derivative, which already contains a synthetic tac promoter (SEQ ID No. 50), by means of recombination with use of the Geneart® Seamless Cloning and Assembly Kit according to the manufacturer's instructions (Life Technologies, Carlsbad, Calif., USA). The transformation of chemically competent E. coli DH5α (New England Biolabs, Frankfurt) was effected in a manner known to those skilled in the art. The correct insertion of the target genes was checked by restriction analysis and the authenticity of the incorporated genes confirmed by DNA sequencing. The resulting expression vectors were designated as pCDF[wax-dgaT_AsADP1(co_Ec)-fadD_Ec] (SEQ ID No. 48) and pCDF[atfA1_Ab(co_Ec)-fadD_Ec] (SEQ ID No. 49).

Example 8 Production of Methyl Aminolaurate by an E. coli Strain with Deletion in the Gene fadE and Expression Vectors for the Genes synUcTE from Umbellularia californica, Ald from Bacillus subtilis, and Cv_(—)2025 from Chromobacterium violaceum in Combination with an Expression Vector for the Genes alkB, alkG, alkT and alkL from the alk operon of Pseudomonas putida and an Expression Vector for the Genes fadD from Escherichia coli and Wax-dgaT from Acinetobacter sp. ADP1 or atfA1 from Alcanivorax borkumensis

Firstly, an E. coli strain with deletion in the gene fadE (SEQ ID No. 40) was constructed. For the production of the gene deletion, a plasmid was constructed which carries the DNA sequence ΔfadE (SEQ ID No. 55). This sequence was synthesized and consists of homologous regions 500 base pairs upstream and downstream from the fadE gene and the recognition sequence for the restriction endonuclease NotI at the 5′ and 3′ end. The sequence ΔfadE was digested with the restriction endonuclease NotI and ligated into the correspondingly cleaved vector pKO3. The strain E. coli W3110 ΔfadE was constructed by means of the pKO3-ΔfadE construct (SEQ ID No. 56) by methods known to those skilled in the art (see Link A J, Phillips D, Church G M. J. Bacteriol. 1997. 179(20)). The DNA sequence of fadE after deletion is reproduced in SEQ ID No. 57.

To create an E. coli strain with expression vectors for the genes synUcTE from Umbellularia californica, ald from Bacillus subtilis, and Cv_(—)2025 from Chromobacterium violaceum in combination with an expression vector for the genes alkB (enzyme E_(1a)), alkG, alkT (auxiliary enzymes to enzyme E_(1b)) and alkL (coding for alkL gene product) from the alk operon of Pseudomonas putida GPo1 and an expression vector for the genes fadD from Escherichia coli and wax-dgaT from Acinetobacter sp. ADP1 or atfA1 from Alcanivorax borkumensis SK2, electrocompetent cells of E. coli W3110 ΔfadE were produced. This took place in a manner known to those skilled in the art. E. coli W3110 ΔfadE was sequentially transformed with the plasmids pBT10_alkL (sequence and production: compare Example 1 of PCT/EP2011/053834 and the Seq ID No. 8 listed there), pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE] (SEQ ID No. 38) and pCDF[wax-dgaT_AsADP1(co_Ec)-fadD_Ec] (SEQ ID No. 48) and pCDF[atfA1_Ab(co_Ec)-fadD_Ec] (SEQ ID No. 49) respectively and plated out onto LB agar plates containing kanamycin (50 μg/ml), ampicillin (100 μg/ml) and spectinomycin (100 μg/ml). Transformants were checked for the presence of the correct plasmids by plasmid preparation and analytical restriction analysis. In this manner the following strains were constructed:

E. coli W3110 ΔfadE pBT10_alkL/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE]/pCDF[wax-dgaT_AsADP1(co_Ec)-fadD_Ec] E. coli W3110 ΔfadE pBT10_alkL/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE]/pCDF[atfA1_Ab(co_Ec)-fadD_Ec]

The strains were subjected to a fed-batch fermentation in order to analyse their capacity for the production of methyl hydroxylaurate, methyl oxolaurate, methyl carboxylaurate and methyl aminolaurate from glucose. This was performed with an 8-fold parallel fermentation system from DASGIP.

For the fermentation, 1 L reactors were used, which were equipped with overhead stirrers and impeller turbines. For process monitoring, pH and pO₂ were measured online. OTR/CTR measurements were used inter alia for estimation of the metabolic selectivity and fitness of the cells.

The pH probes were calibrated by means of a two-point calibration with standard solutions of pH 4.0 and pH 7.0 according to the technical manual of DASGIP. The reactors were equipped with the necessary sensors and connections according to the technical manual and the stirrer shaft mounted. They were filled with 300 mL water and autoclaved for 20 mins at 121° C. to ensure sterility. Next, the pO2 probes were polarized overnight after connection to the measurement amplifier. Next, the water was removed under the clean bench, and replaced by high cell density medium consisting of (NH₄)₂SO4 1.76 g/L, K₂HPO₄ 19.08 g/L, KH₂PO₄ 12.5 g/L, yeast extract 6.66 g/L, trisodium citrate dihydrate 11.2 g, 17mL/L of a separately autoclaved 1% ammonium iron citrate solution, and 5 mL/L of separately autoclaved trace element stock solution (consisting of HCl (37%) 36.50 g/L, MnCl₂*4H₂O 1.91 g/L, ZnSO₄*7H₂O 1.87 g/L, ethylenediaminetetraacetic acid dihydrate 0.84 g/L, H₃BO₃ 0.30 g/L. Na₂MoO₄*2H₂O 0.25 g/L, CaCl₂*2H₂O 4.70 g/L, FeSO₄*7H₂O 17.80 g/L, CuCl₂*2H₂O 0.15 g/L) with 15 g/L glucose as carbon source (added by metering in 30 mL/L of a separately autoclaved feed solution consisting of 500 g/L glucose, 1% (w/v) MgSO₄*7H₂O and 2.2% (w/v) NH₄Cl) containing 100 mg/L ampicillin, 50 mg/L kanamycin and 100 mg/L spectinomycin.

Below, the pO2 probes were calibrated with a one-point calibration (stirrer: 600 rpm/gassing: 10 sL/hr air) and the feed-, correction agent and induction agent lines cleaned by means of Cleaning-in-Place according to the technical manual. For this, the tubes were flushed with 70% ethanol, then with 1 M NaOH, then with sterile demineralized water and finally filled with the respective media.

The strains W3110 ΔfadE pJ294[alaDH_Bs/TAcv(ct)]{Ptac}[synUcTE] pBT10_alkL pCDF[atfA_AsADP1(co_Ec)/fadD] and W3110 ΔfadE

pJ294[alaDH_Bs/TAcv(ct)]{Ptac}[synUcTE] pBT10_alkL pCDF[atfA1_Ab(co_Ec)/fadD] were firstly grown from a cryoculture in LB medium (25 mL in a 100 mL baffle flask) containing 100 mg/L ampicillin, 50 mg/L kanamycin and 100 mg/L spectinomycin overnight at 37° C. and 200 rpm for ca. 18 hrs. Next, 2 mL of this culture were transferred for a second preculture stage into 25 mL of high cell density medium consisting of (NH₄)₂SO₄ 1.76 g/L, K₂HPO₄ 19.08 g/L, KH₂PO₄ 12.5 g/L, yeast extract 6.66 g/L, trisodium citrate dihydrate 11.2 g, 17 mL/L of a separately autoclaved 1% ammonium iron citrate solution, and 5 mL/L of separately autoclaved trace element stock solution (consisting of HCl (37%) 36.50 g/L, MnCl₂*4H₂O 1.91 g/L, ZnSO₄*7H₂O 1.87 g/L, ethylenediaminetetraacetic acid dihydrate 0.84 g/L, H₃BO₃ 0.30 g/L. Na₂MoO₄*2H₂O 0.25 g/L, CaCl₂*2H₂O 4.70 g/L, FeSO₄*7H₂O 17.80 g/L, CuCl₂*2H₂O 0.15 g/L) with 15 g/L glucose as carbon source (added by metering in 30 mL/L of a separately autoclaved feed solution consisting of 500 g/L glucose, 1% (w/v) MgSO₄*7H₂O and 2.2% (w/v) NH₄Cl) containing the antibiotics already described in a 100 mL shaker flask and again incubated at 37° C./200 rpm for a further 6 hrs.

In order to inoculate the reactors with an optical density of 0.1, the OD of the second preculture stage was measured and the quantity of culture required for the inoculation calculated. The required quantity of culture was added to the thermostatted and aerated reactor through a septum by means of a 5 mL syringe.

The following standard programme was used:

DO regulator pH regulator Preset  0% Preset  0 mL/hr P 0.1 P 5 Ti 300 secs Ti 200 secs Min  0% Min  0 mL/hr Max 100% Max  40 mL/hr

N XO2 (gas F (gas (Rotation) from to mixture) from to flow) from to Growth 0% 30% Growth 0% 100% Growth 15% 80% and 400 rpm 1500 rpm and 21% 21% and 6 sL/hr 72 sL/hr biotransformation biotransformation biotransformation

Script Trigger 31% DO (1/60 hr) exactly Induction 2 hrs after feed start IPTG Feed trigger 50% DO Feed rate 3 [mL/hr]

The pH was regulated at pH 6.8 with 12.5% ammonia solution. During growth and biotransformation, the dissolved oxygen (pO₂ or DO) in the culture was regulated to at least 30% via stirrer revolution rate and gassing rate. After inoculation, the DO fell from 100% to this 30%, where it was maintained stable for the remainder of the fermentation.

The fermentation was performed as fed-batch, wherein as entry to the fed phase, with 5 g/Lhr glucose feed consisting of 500 g/L glucose, 1% (w/v) MgSO₄*7H₂O and 2.2% (w/v) NH₄Cl, the feed start was triggered via the DO peak indicating the end of the batch phase. At feed start, the temperature was also lowered from 37° C. to 30° C.

At this time, 24 mL of oleic acid, an oleic acid/hexadecane (1:1 (w/w)) or 2-hexyldecanoic acid/hexadecane mixture (1:1 (w/w)) were added to the reactors. 2 hrs after feed start, the expression of the genes fadD from Escherichia coli and atfA from Acinetobacter sp. ADP1 or atfA1 from Alcanivorax borkumensis SK2 was induced by the automatic addition of a prepared IPTG solution for 1 mM final concentration in the reactor. This IPTG solution also contained 3 mL methanol, which is required for the esterification of the fatty acids produced. The induction of the alkBGT genes was effected by the manual addition of 0.025% (v/v) DCPK 10 hrs after feed start.

During the culturing, samples were withdrawn and the concentration of fatty acids and ω-functionalized fatty acids quantified with the method described below.

For the sampling, 2 mL of fermentation broth were withdrawn from the vessel and a portion thereof diluted 1/10 in an acetonitrile-formic acid mixture (80% (v/v) acetonitrile in water; 0.1% (v/v) formic acid).

The quantification of methyl laurate LSME, methyl ω-hydroxylaurate HLSME, methyl ω-oxolaurate OLSME, methyl ω-aminolaurate ALSME and methyl ω-carboxylaurate DDSME, ω-aminolauric acid ALS, ω-carboxylauric acid DDS, lauric acid LS, ω-hydroxylauric acid HLS and ω-oxolauric acid OLS in the fermentation samples was effected by means of LC-ESI/MS² on the basis of an external calibration for all analytes (0.1-50 mg/L) and with use of the internal standards aminoundecanoic acid (AUD), d4-ALSME, 13C-DDSME and d3-LSME.

For this, the following instruments were used:

-   -   HPLC unit 1260 (Agilent; Böblingen) with autosampler (G1367E),         binary pump (G1312B) and column oven (G1316A)     -   Mass spectrometer TripelQuad 6410 (Agilent; Boblingen) with ESI         source     -   HPLC column: Kinetex C18, 100×2.1 mm, particle size: 2.6 μm,         pore size 100 Å (Phenomenex; Aschaffenburg)     -   Precolumn: KrudKatcher Ultra HPLC in-line filter; 0.5 μm filter         depth and 0.004 mm internal diameter (Phenomenex; Aschaffenburg)

The samples were prepared by pipetting 1900 μL of solvent (80% (v/v) ACN, 20% bidest. H₂O (v/v), +0.1% formic acid) and 100 μL of sample into a 2 mL reaction vessel. The mixture was vortexed for ca. 10 seconds and then centrifuged at ca. 13,000 rpm for 5 mins. The clear supernatant was withdrawn with a pipette and analysed after appropriate dilution with diluent (80% (v/v) ACN, 20% bidest. H₂O (v/v), +0.1% formic acid). 100 μL of ISTD were pipetted into each 900 μL sample (10 μL with a sample volume of 90 μL).

The HPLC separation was effected with the aforementioned column and precolumn. The injection volume was 0.7 μL, the column temperature 50° C. and the flow rate 0.6 mL/min. The mobile phase consisted of eluent A (0.1% (v/v) aqueous formic acid) and eluent B (acetonitrile with 0.1% (v/v) formic acid). The following gradient profile was used

Time [mins] Eluent A [%] Eluent B [%] 0 77 23 0.3 77 23 0.4 40 60 2.5 40 60 2.6 2 98 5.5 2 98 5.6 77 23 9 77 23

The ESI-MS² analysis was effected in positive mode with the following ESI source parameters:

-   -   Gas temperature 280° C.     -   Gas flow rate 11 L/min     -   Nebulizer pressure 50 psi     -   Capillary voltage 4000 V

The detection and quantification of the individual compounds was effected with the following parameters, wherein in each case one product ion was used as Qualifier and one as Quantifier.

Precursor Ion Product Ion Dwell Collision Analyte [m/z] [m/z] time [ms] energy [eV] DDSME 245.2 167.1 25 6 DDSME 245.2 149.1 50 8 HLSME 231.3 181.2 15 2 HLSME 231.3 163.2 25 5 DDS 231.2 213.2 50 0 DDS 231.2 149.1 25 9 ALSME 230.3 198.1 25 10 ALSME 230.3 163.2 15 10 OLSME 229.2 197.2 50 0 OLSME 229.2 161.1 25 5 HLS 217.2 181.2 35 0 HLS 217.2 163.1 20 4 OLS 215.2 161.2 25 0 OLS 215.2 95.2 60 13

It was shown that the strains E. coli W3110 ΔfadE pBT10_alkL/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE]/pCDF[wax-dgaT_AsADP1(co_Ec)-fadD_Ec] and E. coli W3110 ΔfadE pBT10_alkL/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE]/pCDF[atfA1_Ab(co_Ec)-fadD_Ec] with addition of 1% (v/v) methanol are capable of forming methyl laurate, methyl ω-hydroxylaurate, methyl ω-oxolaurate, methyl ω-aminolaurate and methyl ω-carboxylaurate. In addition it could be shown that under these conditions both strains also form lauric acid, ω-hydroxylauric acid, ω-oxolauric acid, ω-aminolauric acid and ω-carboxylauric acid.

Production of ω-functionalized fatty acid methyl esters. The concentrations of methyl laurate, methyl ω-carboxylaurate, methyl ω-hydroxylaurate, methyl ω-oxolaurate and methyl ω-aminolaurate after 38.33 hours fermentation time are stated.

C_(methyl laurate) C_(methyl ω-carboxylaurate) Strain Added organic phase [mg/L] [mg/L] E. coli W3110 ΔfadE pBT10_alkL/ Oleic acid 28.4 1.8 pJ294[alaDH_B.s._TA_C.v.(ct)_Ptac- synUcTE]/pCDF[wax- dgaT_AsADP1(co_Ec)-fadD_Ec] E. coli W3110 ΔfadE pBT10_alkL/ Oleic acid 20.2 0.4 pJ294[alaDH_B.s._TA_C.v.(ct)_Ptac- synUcTE]/pCDF[atfA1_Ab(co_Ec)-fadD_Ec] E. coli W3110 ΔfadE pBT10_alkL/ Oleic acid/ 13.2 1.4 pJ294[alaDH_B.s._TA_C.v.(ct)_Ptac- hexadecane synUcTE]/pCDF[wax- dgaT_AsADP1(co_Ec)-fadD_Ec] E. coli W3110 ΔfadE pBT10_alkL/ 2-hexyl- 7.5 0.9 pJ294[alaDH_B.s._TA_C.v.(ct)_Ptac- decanoic synUcTE]/pCDF[wax- acid/ dgaT_AsADP1(co_Ec)-fadD_Ec] hexadecane C_(methyl ω-hydroxylaurate) C_(methyl ω-oxolaurate) C_(methyl ω-aminolaurate) Strain [mg/L] [mg/L] [mg/L] E. coli W3110 ΔfadE pBT10_alkL/ 4.6 2.0 4.0 pJ294[alaDH_B.s._TA_C.v.(ct)_Ptac- synUcTE]/pCDF[wax- dgaT_AsADP1(co_Ec)-fadD_Ec] E. coli W3110 ΔfadE pBT10_alkL/ 0.8 1.2 2.2 pJ294[alaDH_B.s._TA_C.v.(ct)_Ptac- synUcTE]/pCDF[atfA1_Ab(co_Ec)-fadD_Ec] E. coli W3110 ΔfadE pBT10_alkL/ 2.1 1.3 2.6 pJ294[alaDH_B.s._TA_C.v.(ct)_Ptac- synUcTE]/pCDF[wax- dgaT_AsADP1(co_Ec)-fadD_Ec] E. coli W3110 ΔfadE pBT10_alkL/ 1.7 0.1 40.6 pJ294[alaDH_B.s._TA_C.v.(ct)_Ptac- synUcTE]/pCDF[wax- dgaT_AsADP1(co_Ec)-fadD_Ec]

Example 9 Production of Methyl Aminolaurate by an E. coli Strain with Deletion of the Gene fadE and Expression Vectors for the Genes synUcTE from Umbellularia californica, Ald from Bacillus subtilis, and Cv_(—)2025 from Chromobacterium violaceum in Combination with an Expression Vector for the Genes alkB, alkG and alkT from the alk Operon of Pseudomonas putida and an Expression Vector for the Genes fadD from Escherichia coli and Wax-dgaT from Acinetobacter sp. ADP1 or atfA1 from Alcanivorax borkumensis

To create an E. coli strain with expression vectors for the genes synUcTE from Umbellularia californica, ald from Bacillus subtilis, and Cv_(—)2025 from Chromobacterium violaceum in combination with an expression vector for the genes alkB, alkG and alkT from the alk operon of Pseudomonas putida GPo1 and an expression vector for the genes fadD from Escherichia coli and wax-dgaT from Acinetobacter sp. ADP1 or atfA1 from Alcanivorax borkumensis SK2, electrocompetent cells of E. coli W3110 ΔfadE (construction described in Example 8) are produced. This takes place in a manner known to those skilled in the art. E. coli W3110 ΔfadE is sequentially transformed with the plasmids pBT10 (construction described in practical example B.2 of PCT/EP2008/067447), pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE] (SEQ ID No. 5) and pCDF[wax-dgaT_AsADP1(co_Ec)-fadD_Ec] (SEQ ID No. 16) and pCDF[atfA1_Ab(co_Ec)-fadD_Ec] (SEQ ID No. 17) respectively and plated out onto LB agar plates containing kanamycin (50 μg/ml), ampicillin (100 μg/ml) and spectinomycin (100 μg/ml). Transformants are checked for the presence of the correct plasmids by plasmid preparation and analytical restriction analysis. In this manner, the following strains are constructed:

-   -   E. coli W3110 ΔfadE         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE]/pCDF[wax-dgaT_AsADP1(co_Ec)-fadD_Ec]     -   E. coli W3110 ΔfadE         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE]/pCDF[atfA1_Ab(co_Ec)-fadD_Ec]

The strains are subjected to a fed-batch fermentation in order to analyse their capacity for the production of methyl hydroxylaurate, methyl oxolaurate, methyl carboxylaurate and methyl aminolaurate from glucose. This is performed with an 8-fold parallel fermentation system from DASGIP, as described in Example 8.

It is shown that the strains E. coli W3110 ΔfadE pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE]/pCDF[wax-dgaT_AsADP1(co_Ec)-fadD_Ec] and E. coli W3110 ΔfadE pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE]/pCDF[atfA1_Ab(co_Ec)-fadD_Ec] with addition of 1% (v/v) methanol are capable of forming lauric acid, methyl laurate, methyl ω-hydroxylaurate, methyl ω-oxolaurate, methyl ω-aminolaurate and methyl ω-carboxylaurate.

Example 10 Production of Methyl Aminohexanoate, Methyl Aminooctanoate, Methyl Aminodecanoate, Methyl Aminotetradecanoate and Methyl Amino-9-Hexadecenoate by E. coli Strains without Deletion of an fad Gene and with Deletion of One of the Genes fadA, fadB, fadD, fadE or fadL and Expression Vectors for the Genes synUcTE from Umbellularia californica, ChFATB2 from Cuphea hookeriana, CnFATB3 from Cocos nucifera or CPF 2954 from Clostridium perfringens and Ald from Bacillus subtilis, Cv _(—)2025 from Chromobacterium violaceum in Combination with an Expression Vector for the Genes alkB, alkG and alkT from the alk Operon of Pseudomonas putida and an Expression Vector for the Genes fadD from Escherichia coli and Wax-dgaT from Acinetobacter sp. ADP1 or atfA1 from Alcanivorax borkumensis

To create E. coli strains with expression vectors for the genes synUcTE from Umbellularia californica, ChFATB2 from Cuphea hookeriana (SEQ ID No. 58), CnFATB3 from Cocos nucifera (SEQ ID No. 60) or CPF_(—)2954 from Clostridium perfringens (SEQ ID No. 62) and ald from Bacillus subtilis, and Cv_(—)2025 from Chromobacterium violaceum in combination with an expression vector for the genes alkB, alkG and alkT from the alk operon of Pseudomonas putida GPo1 and an expression vector for the gene fadD from Escherichia coli and wax-dgaT from Acinetobacter sp. ADP1 or atfA1 from Alcanivorax borkumensis SK2, electrocompetent cells of E. coli BW25113, JW5578-1 Kan^(S), JW3822-1 Kan^(S), JW1794-1 Kan^(S), JW5020-1 Kan^(S) and JW2341-1 Kan^(S) are produced. This takes place in a manner known to those skilled in the art.

E. coli JW5578-1 Kan^(S), JW3822-1 Kan^(S), JW1794-1 Kan^(S), JW5020-1 Kan^(S) and JW2341-1 Kan^(S) are derivatives of E. coli E. coli JW5578-1, JW3822-1, JW1794-1, JW5020-1 and JW2341-1 (CGSC, The coli genetic stock center, Yale University, New Haven, USA), and these in turn are E. coli BW25113 derivatives which carry a deletion of the genes fadA (SEQ ID No. 64; coding for enzyme E_(f)), fadB (SEQ ID No. 66; coding for enzyme E_(d) and an enzyme E_(e)), fadD (SEQ ID No. 21; coding for enzyme E_(a)), fadE (SEQ ID No. 40; coding for enzyme E_(b)) and fadL (SEQ ID No. 68; coding for an enzyme which catalyses the transport of fatty acid methyl esters across the outer membrane). The genes fadA, fadB, fadD, fadE and fadL are replaced by a kanamycin cassette. Before the provision of the strain with the expression vectors by means of a helper plasmid, which codes for the Flp recombinase, this is removed in a manner known to those skilled in the art (see Datsenko K. A. and Wanner B. L. (2000) PNAS 97(12):6640-6645), resulting in strains JW5578-1 Kan^(S), JW3822-1 Kan^(S), JW1794-1 Kan^(S), JW5020-1 Kan^(S) and JW2341-1 Kan^(S).

BW25113, JW5578-1 Kan^(S), JW3822-1 Kan^(S), JW1794-1 Kan^(S), JW5020-1 Kan^(S) and JW2341-1 Kan^(S) are sequentially transformed with the plasmids

-   1. pBT10 (construction described in practical example B.2 of     PCT/EP2008/067447), and -   2. pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE] (SEQ ID No. 38),     pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-ChFATB2] (SEQ ID No. 70),     pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CnFATB3] (SEQ ID No. 71), or     pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CPF_(—)2954] (SEQ ID No. 72), and -   3. pCDF[wax-dgaT_AsADP1(co_Ec)-fadD_Ec] (SEQ ID No. 16) or     pCDF[atfA1_Ab(co_Ec)-fadD_Ec] (SEQ ID No. 17)     and plated out onto LB agar plates containing kanamycin (50 μg/ml),     ampicillin (100 μg/ml) and spectinomycin (100 μg/ml). Transformants     are checked for the presence of the correct plasmids by plasmid     preparation and analytical restriction analysis.

The plasmids pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-ChFATB2] (SEQ ID No. 38), pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CnFATB3] (SEQ ID No. 70) and pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CPF_(—)2954] (SEQ ID No. 71) are created starting from the plasmid pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE] (SEQ ID No. 72), in that the gene coding for the thioesterase synUcTE together with P_(tac) and a 3′ flanking region is cut out from the vector via BamHI/NotI and replaced by the genes coding for the thioesterases ChFATB2 (SEQ ID No. 59) CnFATB3 (SEQ ID No. 61) or CPF_(—)2954 (SEQ ID No. 63) (incl. P_(tac) and identical 3′ flanking region). These fragments are created by gene synthesis, wherein the regions coding for ChFATB2 and CnFATB3 are codon-optimized for translation in E. coli, but the region coding for CPF_(—)2954 is not codon-optimized, but instead the wild type sequence is used.

In this manner, inter alia the following strains are constructed:

-   -   E. coli BW25113         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE]/pCDF[wax-dgaT_AsADP1(co_Ec)-fadD_Ec]     -   E. coli BW25113         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE]/pCDF[atfA1_Ab(co_Ec)-fadD_Ec]     -   E. coli JW5578-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE]/pCDF[wax-dgaT_AsADP1(co_Ec)-fadD_Ec]     -   E. coli JW5578-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE]/pCDF[atfA1_Ab(co_Ec)-fadD_Ec]     -   E. coli JW3822-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE]/pCDF[wax-dgaT_AsADP1(co_Ec)-fadD_Ec]     -   E. coli JW3822-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE]/pCDF[atfA1_Ab(co_Ec)-fadD_Ec]     -   E. coli JW1794-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE]/pCDF[wax-dgaT_AsADP1(co_Ec)-fadD_Ec]     -   E. coli JW1794-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE]/pCDF[atfA1_Ab(co_Ec)-fadD_Ec]     -   E. coli JW5020-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE]/pCDF[wax-dgaT_AsADP1(co_Ec)-fadD_Ec]     -   E. coli JW5020-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE]/pCDF[atfA1_Ab(co_Ec)-fadD_Ec]     -   E. coli JW2341-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE]/pCDF[wax-dgaT_AsADP1(co_Ec)-fadD_Ec]     -   E. coli JW2341-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE]/pCDF[atfA1_Ab(co_Ec)-fadD_Ec]

These strains are subjected to a fed-batch fermentation in order to analyse their capacity for production of methyl hydroxylaurate, methyl oxolaurate, methyl carboxylaurate and methyl aminolaurate and methyl hydroxytetradecanoate, methyl oxotetradecanoate, methyl carboxytetradecanoate and methyl aminotetradecanoate from glucose. This is performed with an 8-fold parallel fermentation system from DASGIP, as described in Example 8.

It is shown that these strains, with addition of 1% (v/v) methanol, are capable of forming methyl laurate, methyl hydroxylaurate, methyl oxolaurate, methyl carboxylaurate and methyl aminolaurate and methyl tetradecanoate, methyl hydroxytetradecanoate, methyl oxotetradecanoate, methyl carboxytetradecanoate and methyl aminotetradecanoate from glucose.

Further, the following strains are constructed:

-   -   E. coli BW25113         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-ChFATB2]/pCDF[wax-dgaT_AsADP1(co_Ec)-fadD_Ec]     -   E. coli BW25113         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-ChFATB2]/pCDF[atfA1_Ab(co_Ec)-fadD_Ec]     -   E. coli JW5578-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-ChFATB2]/pCDF[wax-dgaT_AsADP1(co_Ec)-fadD_Ec]     -   E. coli JW5578-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-ChFATB2]/pCDF[atfA1_Ab(co_Ec)-fadD_Ec]     -   E. coli JW3822-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-ChFATB2]/pCDF[wax-dgaT_AsADP1(co_Ec)-fadD_Ec]     -   E. coli JW3822-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-ChFATB2]/pCDF[atfA1_Ab(co_Ec)-fadD_Ec]     -   E. coli JW1794-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-ChFATB2]/pCDF[wax-dgaT_AsADP1(co_Ec)-fadD_Ec]     -   E. coli JW1794-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-ChFATB2]/pCDF[atfA1_Ab(co_Ec)-fadD_Ec]     -   E. coli JW5020-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-ChFATB2]/pCDF[wax-dgaT_AsADP1(co_Ec)-fadD_Ec]     -   E. coli JW5020-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-ChFATB2]/pCDF[atfA1_Ab(co_Ec)-fadD_Ec]     -   E. coli JW2341-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-ChFATB2]/pCDF[wax-dgaT_AsADP1(co_Ec)-fadD_Ec]     -   E. coli JW2341-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-ChFATB2]/pCDF[atfA1_Ab(co_Ec)-fadD_Ec]

These strains are subjected to a fed-batch fermentation in order to analyse their capacity for production of methyl hydroxyoctanoate, methyl oxooctanoate, methyl carboxyoctanoate and methyl aminooctanoate and methyl hydroxydecanoate, methyl oxodecanoate, methyl carboxydecanoate and methyl aminodecanoate from glucose. This is performed with an 8-fold parallel fermentation system from DASGIP, as described in Example 8.

It is shown that these strains, with addition of 1% (v/v) methanol, are capable of forming methyl octanoate, methyl hydroxyoctanoate, methyl oxooctanoate, methyl carboxyoctanoate and methyl aminooctanoate and methyl decanoate, methyl hydroxydecanoate, methyl oxodecanoate, methyl carboxydecanoate and methyl aminodecanoate from glucose.

Further, the following strains are constructed:

-   -   E. coli BW25113         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CnFATB3]/pCDF[wax-dgaT_AsADP1(co_Ec)-fadD_Ec]     -   E. coli BW25113         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CnFATB3]/pCDF[atfA1_Ab(co_Ec)-fadD_Ec]     -   E. coli JW5578-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CnFATB3]/pCDF[wax-dgaT_AsADP1(co_Ec)-fadD_Ec]     -   E. coli JW5578-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CnFATB3]/pCDF[atfA1_Ab(co_Ec)-fadD_Ec]     -   E. coli JW3822-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CnFATB3]/pCDF[wax-dgaT_AsADP1(co_Ec)-fadD_Ec]     -   E. coli JW3822-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CnFATB3]/pCDF[atfA1_Ab(co_Ec)-fadD_Ec]     -   E. coli JW1794-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CnFATB3]/pCDF[wax-dgaT_AsADP1(co_Ec)-fadD_Ec]     -   E. coli JW1794-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CnFATB3]/pCDF[atfA1_Ab(co_Ec)-fadD_Ec]     -   E. coli JW5020-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CnFATB3]/pCDF[wax-dgaT_AsADP1(co_Ec)-fadD_Ec]     -   E. coli JW5020-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CnFATB3]/pCDF[atfA1_Ab(co_Ec)-fadD_Ec]     -   E. coli JW2341-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CnFATB3]/pCDF[wax-dgaT_AsADP1(co_Ec)-fadD_Ec]     -   E. coli JW2341-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CnFATB3]/pCDF[atfA1_Ab(co_Ec)-fadD_Ec]

These strains are subjected to a fed-batch fermentation in order to analyse their capacity for production of methyl hydroxylaurate, methyl oxolaurate, methyl carboxylaurate and methyl aminolaurate and methyl hydroxytetradecanoate, methyl oxotetradecanoate, methyl carboxytetradecanoate and methyl aminotetradecanoate and methyl hydroxy-9-hexadecenoate, methyl oxo-9-hexadecenoate, methyl carboxy-9-hexadecenoate and methyl amino-9-hexadecenoate from glucose. This is performed with an 8-fold parallel fermentation system from DASGIP, as described in Example 8.

It is shown that these strains, with addition of 1% (v/v) methanol, are capable of forming methyl laurate, methyl hydroxylaurate, methyl oxolaurate, methyl carboxylaurate and methyl aminolaurate and methyl tetradecanoate, methyl hydroxytetradecanoate, methyl oxotetradecanoate, methyl carboxytetradecanoate and methyl aminotetradecanoate and methyl 9-hexadecenoate, methyl hydroxy-9-hexadecenoate, methyl oxo-9-hexadecenoate, methyl carboxy-9-hexadecenoate and methyl amino-9-hexadecenoate from glucose.

Finally, the following strains are constructed:

-   -   E. coli BW25113         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CPF_(—)2954]/pCDF[wax-dgaT_AsADP1(co_Ec)-fadD_Ec]     -   E. coli BW25113         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CPF_(—)2954]/pCDF[atfA1_Ab(co_Ec)-fadD_Ec]     -   E. coli JW5578-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CPF_(—)2954]/pCDF[wax-dgaT_AsADP1(co_Ec)-fadD_Ec]     -   E. coli JW5578-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CPF_(—)2954]/pCDF[atfA1_Ab(co_Ec)-fadD_Ec]     -   E. coli JW3822-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CPF_(—)2954]/pCDF[wax-dgaT_AsADP1(co_Ec)-fadD_Ec]     -   E. coli JW3822-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CPF_(—)2954]/pCDF[atfA1_Ab(co_Ec)-fadD_Ec]     -   E. coli JW1794-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CPF_(—)2954]/pCDF[wax-dgaT_AsADP1(co_Ec)-fadD_Ec]     -   E. coli JW1794-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CPF_(—)2954]/pCDF[atfA1_Ab(co_Ec)-fadD_Ec]     -   E. coli JW5020-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CPF_(—)2954]/pCDF[wax-dgaT_AsADP1(co_Ec)-fadD_Ec]     -   E. coli JW5020-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CPF_(—)2954]/pCDF[atfA1_Ab(co_Ec)-fadD_Ec]     -   E. coli JW2341-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CPF_(—)2954]/pCDF[wax-dgaT_AsADP1(co_Ec)-fadD_Ec]     -   E. coli JW2341-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CPF_(—)2954]/pCDF[atfA1_Ab(co_Ec)-fadD_Ec]

These strains are subjected to a fed-batch fermentation in order to analyse their capacity for production of methyl hydroxyoctanoate, methyl oxooctanoate, methyl carboxyoctanoate and methyl aminooctanoate and methyl hydroxyhexanoate, methyl oxohexanoate, methyl carboxyhexanoate and methyl aminohexanoate from glucose. This is performed with an 8-fold parallel fermentation system from DASGIP, as described in Example 8.

It is shown that these strains, with addition of 1% (v/v) methanol, are capable of forming methyl octanoate, methyl hydroxyoctanoate, methyl oxooctanoate, methyl carboxyoctanoate and methyl aminooctanoate and methyl hexanoate, methyl hydroxyhexanoate, methyl oxohexanoate, methyl carboxyhexanoate and methyl aminohexanoate from glucose.

Example 11 Production of Aminohexanoic Acid, Aminooctanoic Acid, Aminodecanoic Acid, Aminotetradecanoic Acid and Amino-9-Hexadecenoic Acid by E. coli Strains with Deletion of One of the Genes fadA, fadB, fadD, fadE or fadL and Expression Vectors for the Genes synUcTE from Umbellularia californica, ChFATB2 from Cuphea hookeriana, CnFATB3 from Cocos nucifera or CPF 2954 from Clostridium perfringens (Genbank Acc. # ABG82470 SEQ-ID XY) and Ald from Bacillus subtilis, Cv _(—)2025 from Chromobacterium violaceum in Combination with an Expression Vector for the Genes alkB, alkG and alkT from the Alk Operon of Pseudomonas putida

To create E. coli strains with expression vectors for the genes synUcTE from Umbellularia californica, ChFATB2 from Cuphea hookeriana (SEQ ID No. 58), CnFATB3 from Cocos nucifera (SEQ ID No. 60) or CPF_(—)2954 from Clostridium perfringens (SEQ ID No. 62) and ald from Bacillus subtilis, and Cv_(—)2025 from Chromobacterium violaceum in combination with an expression vector for the genes alkB, alkG and alkT from the alk operon of Pseudomonas putida GPo1, electrocompetent cells of E. coli JW5578-1 Kan^(S), JW3822-1 Kan^(S), JW1794-1 Kan^(S), JW5020-1 Kan^(S) and JW2341-1 Kan^(S) are produced. This takes place in a manner known to those skilled in the art.

JW5578-1 Kan^(S), JW3822-1 Kan^(S), JW1794-1 Kan^(S), JW5020-1 Kan^(S) and JW2341-1 Kan^(S) are sequentially transformed with the plasmids

-   1. pBT10 (construction described in practical example B.2 of     PCT/EP2008/067447), and -   2. pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE] (SEQ ID No. 38),     pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-ChFATB2] (SEQ ID No. 70),     pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CnFATB3] (SEQ ID No. 71), or     pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CPF_(—)2954] (SEQ ID No. 72)     and plated out onto LB agar plates containing kanamycin (50 μg/ml)     and ampicillin (100 μg/ml). Transformants are checked for the     presence of the correct plasmids by plasmid preparation and     analytical restriction analysis.

In this manner, inter alia the following strains are constructed:

-   -   E. coli BW25113 pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE]     -   E. coli JW5578-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE]     -   E. coli JW3822-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE]     -   E. coli JW1794-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE]     -   E. coli JW5020-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE]     -   E. coli JW2341-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE]

These strains are subjected to a fed-batch fermentation in order to analyse their capacity for production of hydroxylauric acid, oxolauric acid, carboxylauric acid and aminolauric acid and hydroxytetradecanoic acid, oxotetradecanoic acid, carboxytetradecanoic acid and aminotetradecanoic acid from glucose. This is performed with an 8-fold parallel fermentation system from DASGIP, as described in Example 8.

It is shown that these strains are capable of forming lauric acid, hydroxylauric acid, oxolauric acid, carboxylauric acid and aminolauric acid and tetradecanoic acid, hydroxytetradecanoic acid, oxotetradecanoic acid, carboxytetradecanoic acid and aminotetradecanoic acid from glucose.

Further, the following strains are constructed:

-   -   E. coli BW25113 pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-ChFATB2]     -   E. coli JW5578-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-ChFATB2]     -   E. coli JW3822-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-ChFATB2]     -   E. coli JW1794-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-ChFATB2]     -   E. coli JW5020-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-ChFATB2]/     -   E. coli JW2341-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-ChFATB2]

These strains are subjected to a fed-batch fermentation in order to analyse their capacity for production of hydroxyoctanoic acid, oxooctanoic acid, carboxyoctanoic acid and aminooctanoic acid and hydroxydecanoic acid, oxodecanoic acid, carboxydecanoic acid and aminodecanoic acid from glucose. This is performed with an 8-fold parallel fermentation system from DASGIP, as described in Example 8.

It is shown that these strains are capable of forming octanoic acid, hydroxyoctanoic acid, oxooctanoic acid, carboxyoctanoic acid and aminooctanoic acid and decanoic acid, hydroxydecanoic acid, oxodecanoic acid, carboxydecanoic acid and aminodecanoic acid from glucose.

Further, the following strains are constructed:

-   -   E. coli BW25113 pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CnFATB3]     -   E. coli JW5578-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CnFATB3]     -   E. coli JW3822-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CnFATB3]     -   E. coli JW1794-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CnFATB3]     -   E. coli JW5020-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CnFATB3]     -   E. coli JW2341-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CnFATB3]

These strains are subjected to a fed-batch fermentation in order to analyse their capacity for production of hydroxylauric acid, oxolauric acid, carboxylauric acid and aminolauric acid and hydroxytetradecanoic acid, oxotetradecanoic acid, carboxytetradecanoic acid and aminotetradecanoic acid and hydroxy-9-hexadecenoic acid, oxo-9-hexadecenoic acid, carboxy-9-hexadecenoic acid and amino-9-hexadecenoic acid from glucose. This is performed with an 8-fold parallel fermentation system from DASGIP, as described in Example 8.

It is shown that these strains are capable of forming lauric acid, hydroxylauric acid, oxolauric acid, carboxylauric acid and aminolauric acid and tetradecanoic acid, hydroxytetradecanoic acid, oxotetradecanoic acid, carboxytetradecanoic acid and aminotetradecanoic acid and 9-hexadecenoic acid, hydroxy-9-hexadecenoic acid, oxo-9-hexadecenoic acid, carboxy-9-hexadecenoic acid and amino-9-hexadecenoic acid from glucose.

Finally, the following strains are constructed:

-   -   E. coli BW25113         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CPF_(—)2954]     -   E. coli JW5578-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CPF_(—)2954]     -   E. coli JW3822-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CPF_(—)2954]     -   E. coli JW1794-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CPF_(—)2954]     -   E. coli JW5020-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CPF_(—)2954]     -   E. coli JW2341-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CPF_(—)2954]

These strains are subjected to a fed-batch fermentation in order to analyse their capacity for production of hydroxyoctanoic acid, oxooctanoic acid, carboxyoctanoic acid and aminooctanoic acid and hydroxyhexanoic acid, oxohexanoic acid, carboxyhexanoic acid and aminohexanoic acid from glucose. This is performed with an 8-fold parallel fermentation system from DASGIP, as described in Example 8.

It is shown that these strains are capable of forming octanoic acid, hydroxyoctanoic acid, oxooctanoic acid, carboxyoctanoic acid and aminooctanoic acid and hexanoic acid, hydroxyhexanoic acid, oxohexanoic acid, carboxyhexanoic acid and aminohexanoic acid from glucose.

Example 12 Production of Methyl Aminolaurate by an E. coli Strain with Deletion in the Gene fadE and Expression Vectors for the Genes synUcTE from Umbellularia Californica, Ald from Bacillus subtilis, Psyr_(—)4866 from Pseudomonas syringae pv. syringae B728a, PFL_(—)5927 from Pseudomonas protegens Pf-5, PSPPH 4896 from Pseudomonas syringae pv. phaseolicola 1448A or PSPTOT1_(—)2473 from Pseudomonas syringae pv. tomato T1 in Combination with an Expression Vector for the Genes alkB, alkG, alkT and alkL from the Alk Operon of Pseudomonas putida and an Expression Vector for the Genes fadD from Escherichia coli and Wax-dgaT from Acinetobacter sp. ADP1 or atfA1 from Alcanivorax borkumensis

To create E. coli strains with expression vectors for the genes synUcTE from Umbellularia californica, ald from Bacillus subtilis, Psyr_(—)4866 from Pseudomonas syringae pv. syringae B728a (SEQ ID No. 73), PFL_(—)5927 from Pseudomonas protegens Pf-5 (SEQ ID No. 75), PSPPH_(—)4896 from Pseudomonas syringae pv. phaseolicola 1448A (SEQ ID No. 77) or PSPTOT1_(—)2473 from Pseudomonas syringae pv. tomato T1 (SEQ ID No. 79) in combination with an expression vector for the genes alkB, alkG and alkT from the alk operon of Pseudomonas putida GPo1 and an expression vector for the genes fadD from Escherichia coli and wax-dgaT from Acinetobacter sp. ADP1 or atfA1 from Alcanivorax borkumensis, electrocompetent cells of E. coli JW5020-1 Kan^(S) are produced. This takes place in a manner known to those skilled in the art.

JW5020-1 Kan^(S) is sequentially transformed with the plasmids

-   1. pBT10 (construction described in practical example B.2 of     PCT/EP2008/067447), and -   2. pJ294[alaDH_B.s._TA_Psyr_(—)4866_Ptac-synUcTE] (SEQ ID No. 81),     pJ294[alaDH_B.s._TA_PFL_(—)5927_Ptac-synUcTE] (SEQ ID No. 82),     pJ294[alaDH_B.s._TA_PSPPH_(—)4896_Ptac-synUcTE] (SEQ ID No. 83), or     pJ294[alaDH_B.s._TA_PSPTOT1_(—)2473_Ptac-synUcTE] (SEQ ID No. 84),     and -   3. pCDF[wax-dgaT_AsADP1(co_Ec)-fadD_Ec] (SEQ ID No. 16) or     pCDF[affA1_Ab(co_Ec)-fadD_Ec] (SEQ ID No. 17)     and plated out onto LB agar plates containing kanamycin (50 μg/ml),     ampicillin (100 μg/ml) and spectinomycin (100 μg/ml). Transformants     are checked for the presence of the correct plasmids by plasmid     preparation and analytical restriction analysis.

The plasmids pJ294[alaDH_B.s._Psyr_(—)4866_Ptac-synUcTE] (SEQ ID No. 81), pJ294[alaDH_B.s._TA_PFL_(—)5927_Ptac-synUcTE] (SEQ ID No. 82), pJ294[alaDH_B.s._TA_PSPPH_(—)4896_Ptac-synUcTE] (SEQ ID No. 83) and pJ294[alaDH_B.s._TA_PSPTOT1_(—)2473_Ptac-synUcTE] (SEQ ID No. 84) are created starting from the plasmid pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE] (SEQ ID No. 38), in that the gene coding for the transaminase Cv_(—)2025 with the 3′ end of the ald gene from Bacillus subtilis and a 3′ flanking region is cut out from the vector via BglII FseI and replaced by the genes coding for the transaminases Psyr_(—)4866 (SEQ ID No. 74), PFL_(—)5927 (SEQ ID No. 76), PSPPH_(—)4896 (SEQ ID No. 78) or PSPTOT1_(—)2473 (SEQ ID No. 80) (incl. the 3′ end of the ald gene from Bacillus subtilis and identical 3′ flanking region). These fragments are created by gene synthesis, wherein the regions coding for Psyr_(—)4866, PFL_(—)5927, PSPPH_(—)4896 and PSPTOT1_(—)2473 are codon-optimized for translation in E. coli.

In this manner, the following strains are constructed:

-   -   E. coli JW5020-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._Psyr_(—)4866_Ptac-synUcTE]/pCDF[wax-dgaT_AsADP1(co_Ec)-fadD_Ec]     -   E. coli JW5020-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._Psyr_(—)4866_Ptac-synUcTE]/pCDF[atfA1_Ab(co_Ec)-fadD_Ec]     -   E. coli JW5020-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_PFL_(—)5927_Ptac-synUcTE]/pCDF[wax-dgaT_AsADP1(co_Ec)-fadD_Ec]     -   E. coli JW5020-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_PFL_(—)5927_Ptac-synUcTE]/pCDF[atfA1_Ab(co_Ec)-fadD_Ec]     -   E. coli JW5020-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_PSPPH_(—)4896_Ptac-synUcTE]/pCDF[wax-dgaT_AsADP1(co_Ec)-fadD_Ec]     -   E. coli JW5020-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_PSPPH_(—)4896_Ptac-synUcTE]/pCDF[atfA1_Ab(co_Ec)-fadD_Ec]     -   E. coli JW5020-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_PSPTOT1_(—)2473_Ptac-synUcTE]/pCDF[wax-dgaT_AsADP1(co_Ec)-fadD_Ec]     -   E. coli JW5020-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_PSPTOT1_(—)2473_Ptac-synUcTE]/pCDF[atfA1_Ab(co_Ec)-fadD_Ec]

These strains are subjected to a fed-batch fermentation in order to analyse their capacity for production of methyl hydroxylaurate, methyl oxolaurate, methyl carboxylaurate and methyl aminolaurate and methyl hydroxytetradecanoate, methyl oxotetradecanoate, methyl carboxytetradecanoate and methyl aminotetradecanoate from glucose. This is performed with an 8-fold parallel fermentation system from DASGIP, as described in Example 8.

It is shown that these strains, with addition of 1% (v/v) methanol, are capable of forming methyl laurate, methyl hydroxylaurate, methyl oxolaurate, methyl carboxylaurate and methyl aminolaurate and methyl tetradecanoate, methyl hydroxytetradecanoate, methyl oxotetradecanoate, methyl carboxytetradecanoate and methyl aminotetradecanoate from glucose.

Example 13 Production of aminolauric acid by an E. coli strain with deletion in the gene fadE and expression vectors for the genes synUcTE from Umbellularia californica, ald from Bacillus subtilis, Psyr_(—)4866 from Pseudomonas syringae pv. syringae 8728a, PFL_(—)5927 from Pseudomonas protegens Pf-5, PSPPH 4896 from Pseudomonas syringae pv. phaseolicola 1448A or PSPTOT1_(—)2473 from Pseudomonas syringae pv. tomato T1 in Combination with an Expression Vector for the Genes alkB, alkG, alkT and alkL from the Alk Operon of Pseudomonas putida

To create E. coli strains with expression vectors for the genes synUcTE from Umbellularia californica, ald from Bacillus subtilis, Psyr_(—)4866 from Pseudomonas syringae pv. syringae B728a (SEQ ID No. 73), PFL_(—)5927 from Pseudomonas protegens Pf-5 (SEQ ID No. 75), PSPPH_(—)4896 from Pseudomonas syringae pv. phaseolicola 1448A (SEQ ID No. 77) or PSPTOT1_(—)2473 from Pseudomonas syringae pv. tomato T1 (SEQ ID No. 79) in combination with an expression vector for the genes alkB, alkG and alkT from the alk operon of Pseudomonas putida GPo1, electrocompetent cells of E. coli JW5020-1 Kan^(S) are produced. This takes place in a manner known to those skilled in the art.

JW5020-1 Kan^(S) is sequentially transformed with the plasmids

-   1. pBT10 (construction described in practical example B.2 of     PCT/EP2008/067447), and -   2. pJ294[alaDH_B.s._TA_Psyr_(—)4866_Ptac-synUcTE] (SEQ ID No. 81),     pJ294[alaDH_B.s._TA_PFL_(—)5927_Ptac-synUcTE] (SEQ ID No. 82),     pJ294[alaDH_B.s._TA_PSPPH_(—)4896_Ptac-synUcTE] (SEQ ID No. 83), or     pJ294[alaDH_B.s._TA_PSPTOT1_(—)2473_Ptac-synUcTE] (SEQ ID No. 84)     and plated out onto LB agar plates containing kanamycin (50 μg/ml)     and ampicillin (100 μg/ml) t. Transformants are checked for the     presence of the correct plasmids by plasmid preparation and     analytical restriction analysis.

In this manner, the following strains are constructed:

-   -   E. coli JW5020-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._Psyr_(—)4866_Ptac-synUcTE]     -   E. coli JW5020-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_PFL_(—)5927_Ptac-synUcTE]     -   E. coli JW5020-1 Kan^(S)         pBT10pJ294[alaDH_B.s._TA_PSPPH_(—)4896_Ptac-synUcTE]     -   E. coli JW5020-1 Kan^(S)         pBT10pJ294[alaDH_B.s._TA_PSPTOT1_(—)2473_Ptac-synUcTE]

These strains are subjected to fed-batch fermentation in order to analyse their capacity for production of hydroxylauric acid, oxolauric acid, carboxylauric acid and aminolauric acid and hydroxytetradecanoic acid, oxotetradecanoic acid, carboxytetradecanoic acid and aminotetradecanoic acid from glucose. This is performed with an 8-fold parallel fermentation system from DASGIP, as described in Example 8.

It is shown that these strains are capable of forming lauric acid, hydroxylauric acid, oxolauric acid, carboxylauric acid and aminolauric acid and tetradecanoic acid, hydroxytetradecanoic acid, oxotetradecanoic acid, carboxytetradecanoic acid and aminotetradecanoic acid from glucose.

Example 14 Production of Methyl Aminolaurate by an E. coli Strain with Deletion in the Gene fadE and Expression Vectors for the Genes synUcTE from Umbellularia californica, alr2355 from Nostoc sp. PCC 7120, Rleg_(—)1610 from Rhizobium leguminasorum bv. trifolii WSM1325, blr1738 (aldA) from Bradyrhizobium japonicum USDA 110 or BMD 5199 from Bacillus megaterium DSM 319 and Cv_(—)2025 from Chromobacterium violaceum in Combination with an Expression Vector for the Genes alkB, alkG, alkT and alkL from the alk Operon of Pseudomonas putida and an Expression Vector for the Genes fadD from Escherichia coli and Wax-dgaT from Acinetobacter sp. ADP1 or atfA1 from Alcanivorax borkumensis

To create E. coli strains with expression vectors for the genes synUcTE from Umbellularia californica, alr2355 from Nostoc sp. PCC 7120 (SEQ ID No. 85), Rleg 1610 from Rhizobium leguminasorum bv. trifolii WSM1325 (SEQ ID No. 87), blr1738 (aldA) from Bradyrhizobium japonicum USDA 110 (SEQ ID No. 89) or BMD 5199 from Bacillus megaterium DSM 319 (SEQ ID No. 91) and Cv_(—)2025 from Chromobacterium violaceum in combination with an expression vector for the genes alkB, alkG and alkT from the alk operon of Pseudomonas putida GPo1 and an expression vector for the genes fadD from Escherichia coli and wax-dgaT from Acinetobacter sp. ADP1 or atfA1 from Alcanivorax borkumensis, electrocompetent cells of E. coli JW5020-1 Kan^(S) are produced. This takes place in a manner known to those skilled in the art.

JW5020-1 Kan^(S) is sequentially transformed with the plasmids

-   1. pBT10 (construction described in practical example B.2 of     PCT/EP2008/067447), and -   2. pJ294[alr2355_TA_C.v.(Ct)_Ptac-synUcTE] (SEQ ID No. 93),     pJ294[Rleg_(—)1610_TA_C.v.(Ct)_Ptac-synUcTE] (SEQ ID No. 94),     pJ294[blr1738TA_C.v.(Ct)_Ptac-synUcTE] (SEQ ID No. 95), or     pJ294[BMD_(—)5199_TA_C.v.(Ct)_Ptac-synUcTE] (SEQ ID No. 96),     -   and -   3. pCDF[wax-dgaT_AsADP1(co_Ec)-fadD_Ec] (SEQ ID No. 16) bzw.     pCDF[atfA1_Ab(co_Ec)-fadD_Ec] (SEQ ID No. 17)     and plated out onto LB agar plates containing kanamycin (50 μg/ml),     ampicillin (100 μg/ml) and spectinomycin (100 μg/ml). Transformants     are checked for the presence of the correct plasmids by plasmid     preparation and analytical restriction analysis.

The plasmids pJ294[alr2355_TA_C.v.(Ct)_Ptac-synUcTE] (SEQ ID No. 93), pJ294[Rleg_(—)1610_TA_C.v.(Ct)_Ptac-synUcTE] (SEQ ID No. 94), pJ294[blr1738_TA_C.v.(Ct)_Ptac-synUcTE] (SEQ ID No. 95) and pJ294[BMD_(—)5199_TA_C.v.(Ct)_Ptac-synUcTE] (SEQ ID No. 96) are created starting from the plasmid pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE] (SEQ ID No. 38, in that the gene coding for the alanine dehydrogenase from Bacillus subtilis together with the P_(lacUV5) and the 5′ end of the Cv_(—)2025 gene from Chromobacterium violaceum is cut out of the vector via PstI/EcoNI and replaced by the genes coding for the alanine dehydrogenases alr2355 (SEQ ID No. 86), Rleg_(—)1610 (SEQ ID No. 88), blr1738 (SEQ ID No. 90) or BMD_(—)5199 (SEQ ID No. 92) (incl. P_(lacUV5) and the 5′ end of the Cv_(—)2025 gene from Chromobacterium violaceum). These fragments are created by gene synthesis, wherein the regions coding for alr2355, Rleg_(—)1610, blr1738 and BMD_(—)5199 are not codon-optimized for translation in E. coli, but instead the wild type sequences are used.

In this manner, the following strains are constructed:

-   -   E. coli JW5020-1 Kan^(S)         pBT10/pJ294[alr2355_TA_C.v.(Ct)_Ptac-synUcTE]/pCDF[wax-dgaT_AsADP1(co_Ec)-fadD_Ec]     -   E. coli JW5020-1 Kan^(S)         pBT10/pJ294[alr2355_TA_C.v.(Ct)_Ptac-synUcTE]/pCDF[affA1_Ab(co_Ec)-fadD_Ec]     -   E. coli JW5020-1 Kan^(S)         pBT10/pJ294[Rleg_(—)1610_TA_C.v.(Ct)_Ptac-synUcTE]/pCDF[wax-dgaT_AsADP1(co_Ec)-fadD_Ec]     -   E. coli JW5020-1 Kan^(S)         pBT10/pJ294[Rleg_(—)1610_TA_C.v.(Ct)_Ptac-synUcTE]/pCDF[affA1_Ab(co_Ec)-fadD_Ec]     -   E. coli JW5020-1 Kan^(S)         pBT10/pJ294[blr1738_TA_C.v.(Ct)_Ptac-synUcTE]/pCDF[wax-dgaT_AsADP1(co_Ec)-fadD_Ec]     -   E. coli JW5020-1 Kan^(S)         pBT10/pJ294[blr1738_TA_C.v.(Ct)_Ptac-synUcTE]/pCDF[atfA1_Ab(co_Ec)-fadD_Ec]     -   E. coli JW5020-1 Kan^(S)         pBT10/pJ294[BMD_(—)5199_TA_C.v.(Ct)_Ptac-synUcTE]/pCDF[wax-dgaT_AsADP1(co_Ec)-fadD_Ec]     -   E. coli JW5020-1 Kan^(S)         pBT10/pJ294[BMD_(—)5199_TA_C.v.(Ct)_Ptac-synUcTE]/pCDF[atfA1_Ab(co_Ec)-fadD_Ec]

These strains are subjected to a fed-batch fermentation in order to analyse their capacity for production of methyl hydroxylaurate, methyl oxolaurate, methyl carboxylaurate and methyl aminolaurate and methyl hydroxytetradecanoate, methyl oxotetradecanoate, methyl carboxytetradecanoate and methyl aminotetradecanoate from glucose. This is performed with an 8-fold parallel fermentation system from DASGIP, as described in Example 8.

It is shown that these strains, with addition of 1% (v/v) methanol, are capable of forming methyl laurate, methyl hydroxylaurate, methyl oxolaurate, methyl carboxylaurate and methyl aminolaurate and methyl tetradecanoate, methyl hydroxytetradecanoate, methyl oxotetradecanoate, methyl carboxytetradecanoate and methyl aminotetradecanoate from glucose.

Example 15 Production of Aminolauric Acid by an E. coli Strain with Deletion in the Gene fadE and Expression Vectors for the Genes synUcTE from Umbellularia californica, Alr2355 from Nostoc sp. PCC 7120, Rleg_(—)1610 from Rhizobium leguminasorum bv. trifolii WSM1325, blr1738 (aldA) from Bradyrhizobium japonicum USDA 110 or BMD 5199 from Bacillus megaterium DSM 319 and Cv_(—)2025 from Chromobacterium violaceum in Combination with an Expression Vector for the Genes alkB, alkG, alkT and alkL from the Alk Operon of Pseudomonas putida

To create E. coli strains with expression vectors for the genes synUcTE from Umbellularia californica, alr2355 from Nostoc sp. PCC 7120 (SEQ ID No. 85), Rleg_(—)1610 from Rhizobium leguminasorum bv. trifolii WSM1325 (SEQ ID No. 87), blr1738 (aldA) from Bradyrhizobium japonicum USDA 110 (SEQ ID No. 89) or BMD 5199 from Bacillus megaterium DSM 319 (SEQ ID No. 91) and Cv_(—)2025 from Chromobacterium violaceum in combination with an expression vector for the genes alkB, alkG and alkT from the alk operon of Pseudomonas putida GPo1, electrocompetent cells of E. coli JW5020-1 Kan^(S) are produced. This takes place in a manner known to those skilled in the art.

JW5020-1 Kan^(S) is sequentially transformed with the plasmids

-   1. pBT10 (construction described in practical example B.2 of     PCT/EP2008/067447), and -   2. pJ294[alr2355_TA_C.v.(Ct)_Ptac-synUcTE] (SEQ ID No. 93),     pJ294[Rleg_(—)1610_TA_C.v.(Ct)_Ptac-synUcTE] (SEQ ID No. 94),     pJ294[blr1738_TA_C.v.(Ct)_Ptac-synUcTE] (SEQ ID No. 95), or     pJ294[BMD_(—)5199_TA_C.v.(Ct)_Ptac-synUcTE] (SEQ ID No. 96)     and plated out onto LB agar plates containing kanamycin (50 μg/ml)     and ampicillin (100 μg/ml). Transformants are checked for the     presence of the correct plasmids by plasmid preparation and     analytical restriction analysis.

In this manner, the following strains are constructed:

-   -   E. coli JW5020-1 Kan^(S)         pBT10/pJ294[alr2355_TA_C.v.(Ct)_Ptac-synUcTE]     -   E. coli JW5020-1 Kan^(S)         pBT10/pJ294[Rleg_(—)1610_TA_C.v.(Ct)_Ptac-synUcTE]     -   E. coli JW5020-1 Kan^(S)         pBT10/pJ294[blr1738_TA_C.v.(Ct)_Ptac-synUcTE]     -   E. coli JW5020-1 Kan^(S)         pBT10/pJ294[BMD_(—)5199_TA_C.v.(Ct)_Ptac-synUcTE]

These strains are subjected to a fed-batch fermentation in order to analyse their capacity for production of hydroxylauric acid, oxolauric acid, carboxylauric acid and aminolauric acid and hydroxytetradecanoic acid, oxotetradecanoic acid, carboxytetradecanoic acid and aminotetradecanoic acid from glucose. This is performed with an 8-fold parallel fermentation system from DASGIP, as described in Example 8.

It is shown that these strains are capable of forming lauric acid, hydroxylauric acid, oxolauric acid, carboxylauric acid and aminolauric acid and tetradecanoic acid, hydroxytetradecanoic acid, oxotetradecanoic acid, carboxytetradecanoic acid and aminotetradecanoic acid from glucose.

Example 16 Production of Methyl Aminolaurate by an E. coli Strain with Deletion in the Gene fadE and Expression Vectors for the Genes synUcTE from Umbellularia californica and Cv_(—)2025 from Chromobacterium violaceum in Combination with an Expression Vector for the Genes alkB, alkG, alkT and alkL from the Alk Operon of Pseudomonas putida and an Expression Vector for the Genes fadD from Escherichia coli and Wax-dgaT from Acinetobacter sp. ADP1 or atfA 1 from Alcanivorax borkumensis

To create E. coli strains with expression vectors for the genes synUcTE from Umbellularia californica and Cv_(—)2025 from Chromobacterium violaceum in combination with an expression vector for the genes alkB, alkG and alkT from the alk operon of Pseudomonas putida GPo1 and an expression vector for the genes fadD from Escherichia coli and wax-dgaT from Acinetobacter sp. ADP1 or atfA1 from Alcanivorax borkumensis, electrocompetent cells of E. coli JW5020-1 Kan^(S) are produced. This takes place in a manner known to those skilled in the art.

JW5020-1 Kan^(S) is sequentially transformed with the plasmids

-   1. pBT10 (construction described in practical example B.2 of     PCT/EP2008/067447), and -   2. pJ294[TA_C.v.(Ct)_Ptac-synUcTE] (SEQ ID No. 97), and -   3. pCDF[wax-dgaT_AsADP1(co_Ec)-fadD_Ec] (SEQ ID No. 16), or     pCDF[atfA1_Ab(co_Ec)-fadD_Ec] (SEQ ID No. 17)     and plated out onto LB agar plates containing kanamycin (50 μg/ml),     ampicillin (100 μg/ml) and spectinomycin (100 μg/ml). Transformants     are checked for the presence of the correct plasmids by plasmid     preparation and analytical restriction analysis.

The plasmid pJ294[TA_C.v.(Ct)_Ptac-synUcTE] (SEQ ID No. 97) is created starting from the plasmid pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE] (SEQ ID No. 38), in that parts of the gene coding for the alanine dehydrogenase from Bacillus subtilis essential for functional expression are cut out from the vector with PmeI/SnaBI and this is then religated.

In this manner, the following strains are constructed:

-   -   E. coli JW5020-1 Kan^(S)         pBT10/pJ294[TA_C.v.(Ct)_Ptac-synUcTE]/pCDF[wax-dgaT_AsADP1(co_Ec)-fadD_Ec]     -   E. coli JW5020-1 Kan^(S)         pBT10/pJ294[TA_C.v.(Ct)_Ptac-synUcTE]/pCDF[atfA1_Ab(co_Ec)-fadD_Ec]

These strains are subjected to a fed-batch fermentation in order to analyse their capacity for production of methyl hydroxylaurate, methyl oxolaurate, methyl carboxylaurate and methyl aminolaurate and methyl hydroxytetradecanoate, methyl oxotetradecanoate, methyl carboxytetradecanoate and methyl aminotetradecanoate from glucose. This is performed with an 8-fold parallel fermentation system from DASGIP, as described in Example 8.

It is shown that these strains, with addition of 1% (v/v) methanol, are capable of forming methyl laurate, methyl hydroxylaurate, methyl oxolaurate, methyl carboxylaurate and methyl aminolaurate and methyl tetradecanoate, methyl hydroxytetradecanoate, methyl oxotetradecanoate, methyl carboxytetradecanoate and methyl aminotetradecanoate from glucose.

Example 17 Production of Aminolauric Acid by an E. coli Strain with Deletion in the Gene fadE and Expression Vectors for the Genes synUcTE from Umbellularia californica and Cv_(—)2025 from Chromobacterium violaceum in Combination with an Expression Vector for the Genes alkB, alkG, alkT and alkL from the Alk Operon of Pseudomonas putida

To create E. coli strains with expression vectors for the genes synUcTE from Umbellularia californica and Cv_(—)2025 from Chromobacterium violaceum in combination with an expression vector for the genes alkB, alkG and alkT from the alk operon of Pseudomonas putida GPo1, electrocompetent cells of E. coli JW5020-1 Kan^(S) are produced. This takes place in a manner known to those skilled in the art.

JW5020-1 Kan^(S) is sequentially transformed with the plasmids

-   1. pBT10 (construction described in practical example B.2 of     PCT/EP2008/067447), and -   2. pJ294[TA_C.v.(Ct)_Ptac-synUcTE] (SEQ ID No. 97)     and plated out onto LB agar plates containing kanamycin (50 μg/ml)     and ampicillin (100 μg/ml). Transformants are checked for the     presence of the correct plasmids by plasmid preparation and     analytical restriction analysis.

In this manner, the following strain is constructed:

-   -   E. coli JW5020-1 Kan^(S) pBT10/pJ294[TA_C.v.(Ct)_Ptac-synUcTE]

This strain is subjected to a fed-batch fermentation in order to analyse its capacity for the production of hydroxylauric acid, oxolauric acid, carboxylauric acid and aminolauric acid and hydroxytetradecanoic acid, oxotetradecanoic acid, carboxytetradecanoic acid and aminotetradecanoic acid from glucose. This is performed with an 8-fold parallel fermentation system from DASGIP, as described in Example 8.

It is shown that this strain is capable of producing lauric acid, hydroxylauric acid, oxolauric acid, carboxylauric acid and aminolauric acid and tetradecanoic acid, hydroxytetradecanoic acid, oxotetradecanoic acid, carboxytetradecanoic acid and aminotetradecanoic acid from glucose.

Example 18 Production of methyl aminolaurate by an E. coli strain with deletion in the gene fadE and an expression vector for the gene synUcTE from Umbellularia californica in combination with an expression vector for the genes alkB, alkG, alkT and alkL from the alk operon of Pseudomonas putida and an expression vector for the gene fadD from Escherichia coli and wax-dgaT from Acinetobacter sp. ADP1 or atfA 1 from Alcanivorax borkumensis

To create E. coli strains with an expression vector for the gene synUcTE from Umbellularia californica in combination with an expression vector for the genes alkB, alkG and alkT from the alk operon of Pseudomonas putida GPo1 and an expression vector for the genes fadD from Escherichia coli and wax-dgaT from Acinetobacter sp. ADP1 or atfA1 from Alcanivorax borkumensis, electrocompetent cells of E. coli JW5020-1 Kan^(S) are produced. This takes place in a manner known to those skilled in the art.

JW5020-1 Kan^(S) is sequentially transformed with the plasmids

-   1. pBT10 (construction described in practical example B.2 of     PCT/EP2008/067447), and -   2. pJ294[Ptac-synUcTE] (SEQ ID No. 98), and -   3. pCDF[wax-dgaT_AsADP1(co_Ec)-fadD_Ec] (SEQ ID No. 16), or     pCDF[affA1_Ab(co_Ec)-fadD_Ec] (SEQ ID No. 17)     and plated out onto LB agar plates containing kanamycin (50 μg/ml),     ampicillin (100 μg/ml) and spectinomycin (100 μg/ml). Transformants     are checked for the presence of the correct plasmids by plasmid     preparation and analytical restriction analysis.

The plasmid pJ294[Ptac-synUcTE] (SEQ ID No. 98) is created starting from the plasmid pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE] (SEQ ID No. 38), in that parts of the genes coding for the alanine dehydrogenase from Bacillus subtilis and the transaminase Cv_(—)2025 from Chromobacterium violaceum essential for functional expression are cut out from the vector with SrfI/SnaBI and this is then religated.

In this manner, the following strains are constructed:

-   -   E. coli JW5020-1 Kan^(S)         pBT10/pJ294[Ptac-synUcTE]/pCDF[wax-dgaT_AsADP1(co_Ec)-fadD_Ec]     -   E. coli JW5020-1 Kan^(S)         pBT10/pJ294[Ptac-synUcTE]/pCDF[atfA1_Ab(co_Ec)-fadD_Ec]

These strains are subjected to a fed-batch fermentation in order to analyse their capacity for production of methyl hydroxylaurate, methyl oxolaurate and methyl carboxylaurate and methyl hydroxytetradecanoate, methyl oxotetradecanoate and methyl carboxytetradecanoate from glucose. This is performed with an 8-fold parallel fermentation system from DASGIP, as described in Example 8.

It is shown that these strains, with addition of 1% (v/v) methanol, are capable of forming methyl laurate, methyl hydroxylaurate, methyl oxolaurate and methyl carboxylaurate and methyl tetradecanoate, methyl hydroxytetradecanoate, methyl oxotetradecanoate and methyl carboxytetradecanoate from glucose.

Example 19 Production of Aminolauric Acid by an E. coli Strain with Deletion in the Gene fadE and an Expression Vector for the Gene synUcTE from Umbellularia californica in Combination with an Expression Vector for the Genes alkB, alkG, alkT and alkL from the Alk Operon of Pseudomonas putida

To create E. coli strains with an expression vector for the gene synUcTE from Umbellularia californica in combination with an expression vector for the genes alkB, alkG and alkT from the alk operon of Pseudomonas putida GPo1, electrocompetent cells of E. coli JW5020-1 Kan^(S) are produced. This takes place in a manner known to those skilled in the art.

JW5020-1 Kan^(S) is sequentially transformed with the plasmids

-   1. pBT10 (construction described in practical example B.2 of     PCT/EP2008/067447), and -   2. pJ294[Ptac-synUcTE] (SEQ ID No. 96)     and plated out onto LB agar plates containing kanamycin (50 μg/ml)     and ampicillin (100 μg/ml). Transformants are checked for the     presence of the correct plasmids by plasmid preparation and     analytical restriction analysis.

In this manner, the following strain is constructed:

-   -   E. coli JW5020-1 Kan^(S) pBT10/pJ294[Ptac-synUcTE]

This strain is subjected to a fed-batch fermentation in order to analyse its capacity for the production of hydroxylauric acid, oxolauric acid and carboxylauric acid and hydroxytetradecanoic acid, oxotetradecanoic acid and carboxytetradecanoic acid from glucose. This is performed with an 8-fold parallel fermentation system from DASGIP, as described in Example 8. It is shown that this strain is capable of producing lauric acid, hydroxylauric acid, oxolauric acid and carboxylauric acid and tetradecanoic acid, hydroxytetradecanoic acid, oxotetradecanoic acid and carboxytetradecanoic acid from glucose.

Example 20 Production of Methyl Aminohexanoate, Methyl Aminooctanoate, Methyl Aminodecanoate, Methyl Aminotetradecanoate and Methyl Amino-9-Hexadecenoate by E. coli Strains with Deletion of the fadE Gene and Expression Vectors for the Genes synUcTE from Umbellularia californica, ChFATB2 from Cuphea hookeriana, CnFATB3 from Cocos nucifera or CPF 2954 from Clostridium perfringens and Ald from Bacillus subtilis, Cv_(—)2025 from Chromobacterium violaceum in Combination with an Expression Vector for the Genes alkB, alkG and alkT from the Alk Operon of Pseudomonas putida and an Expression Vector for the Gene Mmar_(—)3356 from Mycobacterium marinum or the Gene ′tesA* from E. coli

To create E. coli strains with expression vectors for the genes synUcTE from Umbellularia californica, ChFATB2 from Cuphea hookeriana (SEQ ID No. 58), CnFATB3 from Cocos nucifera (SEQ ID No. 60) or CPF 2954 from Clostridium perfringens (SEQ ID No. 62) and ald from Bacillus subtilis, and Cv_(—)2025 from Chromobacterium violaceum in combination with an expression vector for the genes alkB, alkG and alkT from the alk operon of Pseudomonas putida GPo1 and an expression vector for the gene Mmar_(—)3356 from Mycobacterium marinum (SEQ ID No. 99) or the gene ′tesA* from E. coli (SEQ ID No. 101), electrocompetent cells of E. coli JW5020-1 Kan^(S) are produced. This takes place in a manner known to those skilled in the art.

JW5020-1 Kan^(S) is sequentially transformed with the plasmids

-   -   pBT10 (construction described in practical example B.2 of         PCT/EP2008/067447), and     -   pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE] (SEQ ID No. 38),         pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-ChFATB2] (SEQ ID No. 70),         pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CnFATB3] (SEQ ID No. 71), or         pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CPF_(—)2954] (SEQ ID No. 72),         and     -   pCDF[Mmar_(—)3356] (SEQ ID No. 103), or pCDF[Ec′tesA*] (SEQ ID         No. 104)         and plated out onto LB agar plates containing kanamycin (50         μg/ml), ampicillin (100 μg/ml) and spectinomycin (100 μg/ml).         Transformants are checked for the presence of the correct         plasmids by plasmid preparation and analytical restriction         analysis.

The plasmids pCDF[Mmar_(—)3356] (SEQ ID No. 103) and pCDF[Ec′tesA*] (SEQ ID No. 104) are created starting from the plasmid pCDF[wax-dgaT_AsADP1(co_Ec)-fadD_Ec] (SEQ ID No. 16), in that the wax-dgaT gene from Acinetobacter sp. ADP1 and the fadD gene from E. coli are cut out from the vector with BamHI/XhoI incl. P_(tac) and the 3′-flanking region of fadD and replaced by the genes coding for the fatty acid O-methyltransferase Mmar_(—)3356 (SEQ ID No. 100) or the acyl-ACP: methanol O-methyltransferase ′TesA* (SEQ ID No. 102) (incl. P_(tac) and the region identical to the 3′-flanking region of fadD). These fragments are created by gene synthesis, wherein the region coding for the fatty acid O-methyltransferase is codon-optimized for translation in E. coli, while the region coding for the thioester transesterase ′TesA* is not codon-optimized for translation in E. coli, but instead the wild type sequence is used.

In this manner, the following strains are constructed:

-   -   E. coli JW5020-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE]/pCDF[Mmar_(—)3356]     -   E. coli JW5020-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-ChFATB2]/pCDF[Mmar_(—)3356]     -   E. coli JW5020-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CnFATB3]/pCDF[Mmar_(—)3356]     -   E. coli JW5020-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CPF_(—)2954]/pCDF[Mmar_(—)3356]     -   E. coli JW5020-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE]/pCDF[Ec′tesA*]     -   E. coli JW5020-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-ChFATB2]/pCDF[Ec′tesA*]     -   E. coli JW5020-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CnFATB3]/pCDF[Ec′tesA*]     -   E. coli JW5020-1 Kan^(S)         pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CPF_(—)2954]/pCDF[Ec′tesA*]

These strains are subjected to a fed-batch fermentation in order to analyse their capacity for production of hydroxy fatty acid methyl esters, oxo fatty acid methyl esters, carboxy fatty acid methyl esters and amino fatty acid methyl esters from glucose. This is performed with an 8-fold parallel fermentation system from DASGIP, as described in Example 8.

It is shown that the strains E. coli JW5020-1 Kan^(S) pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE]/pCDF[Mmar_(—)3356] and E. coli JW5020-1 Kan^(S) pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE]/pCDF[Ec′tesA*], with addition of 1% (v/v) methanol, are capable of forming methyl laurate, methyl hydroxylaurate, methyl oxolaurate, methyl carboxylaurate and methyl aminolaurate and methyl tetradecanoate, methyl hydroxytetradecanoate, methyl oxotetradecanoate, methyl carboxytetradecanoate and methyl aminotetradecanoate from glucose.

It is shown that the strains E. coli JW5020-1 Kan^(S) pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-ChFATB2]/pCDF[Mmar_(—)3356] and E. coli JW5020-1 Kan^(S) pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-ChFATB2]/pCDF[Ec′tesA*], with addition of 1% (v/v) methanol, are capable of forming methyl octanoate, methyl hydroxyoctanoate, methyl oxooctanoate, methyl carboxyoctanoate and methyl aminooctanoate and methyl decanoate, methyl hydroxydecanoate, methyl oxodecanoate, methyl carboxydecanoate and methyl aminodecanoate from glucose.

It is shown that the strains E. coli JW5020-1 Kan^(S) pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CnFATB3]/pCDF[Mmar_(—)3356] and E. coli JW5020-1 Kan^(S) pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CnFATB3]/pCDF[Ec′tesA*], with addition of 1% (v/v) methanol, are capable of forming methyl laurate, methyl hydroxylaurate, methyl oxolaurate, methyl carboxylaurate and methyl aminolaurate and methyl tetradecanoate, methyl hydroxytetradecanoate, methyl oxotetradecanoate, methyl carboxytetradecanoate and methyl aminotetradecanoate and methyl 9-hexadecenoate, methyl hydroxy-9-hexadecenoate, methyl oxo-9-hexadecenoate, methyl carboxy-9-hexadecenoate and methyl amino-9-hexadecenoate from glucose.

It is shown that the strains E. coli JW5020-1 Kan^(S) pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CnFATB3]/pCDF[Mmar_(—)3356] and E. coli JW5020-1 Kan^(S) pBT10/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-CnFATB3]/pCDF[Ec′tesA*], with addition of 1% (v/v) methanol, are capable of forming methyl octanoate, methyl hydroxyoctanoate, methyl oxooctanoate, methyl carboxyoctanoate and methyl aminooctanoate and methyl hexanoate, methyl hydroxyhexanoate, methyl oxohexanoate, methyl carboxyhexanoate and methyl aminohexanoate from glucose.

Example 21 Production of Methyl Aminolaurate and Methyl Aminotetradecanoate by E. coli Strains with Deletion of the Gene fadE and Expression Vectors for the Genes synUcTE from Umbellularia californica, and Ald from Bacillus subtilis, and Cv_(—)2025 from Chromobacterium violaceum in Combination with an Expression Vector for the Genes alkM, alkG and alkT from the Alk Operon of Acinetobacter sp. ADP1 or alkS, alkT, alkB1, alkG and alkT from the Alk Operon of Marinobacter aquaeoli VT8 and an Expression Vector for the Genes fadD from Escherichia coli and Wax-dgaT from Acinetobacter sp. ADP1 or affA1 from Alcanivorax borkumensis

To create E. coli strains with expression vectors for the genes synUcTE from Umbefiularia californica and ald from Bacillus subtilis and Cv_(—)2025 from Chromobacterium violaceum in combination with expression vectors for the genes alkM, alkG and alkT from the alk operon of Acinetobacter sp. ADP1 (SEQ ID No. 105) or alkS, alkT, alkB1, alkG and alkT from the alk operon of Marinobacter aquaeoli VT8 (SEQ ID No. 106) and an expression vector for the genes fadD from Escherichia coli and wax-dgaT from Acinetobacter sp. ADP1 or atfA1 from Alcanivorax borkumensis SK2, electrocompetent cells of E. coli JW5020-1 Kan^(S) are produced. This takes place in a manner known to those skilled in the art.

JW5020-1 Kan^(S) is sequentially transformed with the plasmids

-   4. pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE] (SEQ ID No. 38), -   5. pCDF[wax-dgaT_AsADP1(co_Ec)-fadD_Ec] (SEQ ID No. 16) bzw.     pCDF[atfA1_Ab(co_Ec)-fadD_Ec] (SEQ ID No. 17) -   6. pCOM10-AcalkMGT (SEQ ID No. 107) pCOM10-MaalkST-B1G (SEQ ID No.     108)     and plated out onto LB agar plates containing kanamycin (50 μg/ml),     ampicillin (100 μg/ml) and spectinomycin (100 μg/ml). Transformants     are checked for the presence of the correct plasmids by plasmid     preparation and analytical restriction analysis.

The plasmids pCOM10-AcalkMGT (SEQ ID No. 107) and pCOM10-MaalkST-B1G (SEQ ID No. 108) are created starting from the plasmid pCOM10 (SEQ ID No. 109; Smits T H, Seeger M A, Witholt B, van Beilen J B. New alkane-responsive expression vectors for Escherichia coli and Pseudomonas. Plasmid. 2001. 46(1):16-24.). For this, pCOM10 is cleaved with XhoI/BamHI (pCOM10-MaalkST-B1G) or EcoRI (pCOM10-AcalkMGT) and the loci Acinetobacter sp. ADP1 alkMGT or Marinobacter aquaeoli VT8 alkST-alkB1G respectively inserted into pCOM10. These loci are created by gene synthesis, wherein the regions coding for Acinetobacter sp. ADP1 AlkM (SEQ ID No. 110), AlkG (SEQ ID No. 111) and AlkT (SEQ ID No. 112) and those coding for Marinobacter aquaeoli VT8 AlkS (SEQ ID No. 113), AlkT (SEQ ID No. 114), AlkB1 (SEQ ID No. 115) and AlkG (SEQ ID No. 116) are not codon-optimized for translation in E. coli, but instead the wild type sequence is used.

In this manner, the following strains are constructed:

-   -   E. coli JW5020-1 Kan^(S)         pCOM10-AcalkMGT/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE]/pCDF[wax-dgaT_AsADP1(co_Ec)-fadD_Ec]     -   E. coli JW5020-1 Kan^(S)         pCOM10-AcalkMGT/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE]/pCDF[atfA1_Ab(co_Ec)-fadD_Ec]     -   E. coli JW5020-1 Kan^(S)         pCOM10-MaalkST-B1G/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE]/pCDF[wax-dgaT_AsADP1(co_Ec)-fadD_Ec]     -   E. coli JW5020-1 Kan^(S)         pCOM10-MaalkST-B1G/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE]/pCDF[atfA1_Ab(co_Ec)-fadD_Ec]

These strains are subjected to a fed-batch fermentation in order to analyse their capacity for production of hydroxy fatty acid methyl esters, oxo fatty acid methyl esters, carboxy fatty acid methyl esters and amino fatty acid methyl esters from glucose. This is performed with an 8-fold parallel fermentation system from DASGIP, as described in Example 8.

It is shown that, with addition of 1% (v/v) methanol, these strains are capable of forming methyl laurate, methyl hydroxylaurate, methyl oxolaurate, methyl carboxylaurate and methyl aminolaurate and methyl tetradecanoate, methyl hydroxytetradecanoate, methyl oxotetradecanoate, methyl carboxytetradecanoate and methyl aminotetradecanoate from glucose.

Example 22 Production of Aminolauric Acid and Aminotetradecanoic Acid by E. coli Strains with Deletion of the Gene fadE and Expression Vectors for the Genes synUcTE from Umbellularia californica, and ald from Bacillus subtilis, and Cv_(—)2025 from Chromobacterium violaceum in Combination with an Expression Vector for the Genes alkM, alkG and alkT from the Alk Operon of Acinetobacter sp. ADP1 or alkS, alkT, alkB1, alkG and alkT from the Alk Operon of Marinobacter aquaeoli VT8

To create E. coli strains with expression vectors for the genes synUcTE from Umbellularia californica and ald from Bacillus subtilis and Cv_(—)2025 from Chromobacterium violaceum in combination with expression vectors for the genes alkM, alkG and alkT from the alk operon of Acinetobacter sp. ADP1 (SEQ ID No. 105) or alkS, alkT, alkB1, alkG and alkT from the alk operon of Marinobacter aquaeoli VT8 (SEQ ID No. 106), electrocompetent cells of E. coli JW5020-1 Kan^(S) are produced. This takes place in a manner known to those skilled in the art.

JW5020-1 Kan^(S) is sequentially transformed with the plasmids

-   1. pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE] (SEQ ID No. 38), -   2. pCOM10-AcalkMGT (SEQ ID No. 107) pCOM10-MaalkST-B1G (SEQ ID No.     108)     and plated out onto LB agar plates containing kanamycin (50 μg/ml)     and ampicillin (100 μg/ml). Transformants are checked for the     presence of the correct plasmids by plasmid preparation and     analytical restriction analysis.

In this manner, the following strains are constructed:

-   -   E. coli JW5020-1 Kan^(S)         pCOM10-AcalkMGT/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE]     -   E. coli JW5020-1 Kan^(S)         pCOM10-AcalkMGT/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE]     -   E. coli JW5020-1 Kan^(S)         pCOM10-MaalkST-B1G/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE]     -   E. coli JW5020-1 Kan^(S)         pCOM10-MaalkST-B1G/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE]

These strains are subjected to a fed-batch fermentation in order to analyse their capacity for production of hydroxy fatty acids, oxo fatty acids, carboxy fatty acids and amino fatty acids from glucose. This is performed with an 8-fold parallel fermentation system from DASGIP, as described in Example 8.

It is shown that these strains are capable of forming lauric acid, hydroxylauric acid, oxolauric acid, carboxylauric acid and aminolauric acid and tetradecanoic acid, hydroxytetradecanoic acid, oxotetradecanoic acid, carboxytetradecanoic acid and aminotetradecanoic acid from glucose.

Example 23 Production of Methyl Aminolaurate and Methyl Aminotetradecanoate by E. coli Strains with Deletion of the Gene fadE and Expression Vectors for the Genes synUcTE from Umbellularia californica, and Ald from Bacillus subtilis, and Cv_(—)2025 from Chromobacterium violaceum in Combination with an Expression Vector for the Genes ABO_(—)0200, ABO_(—)0201 and ABO_(—)0203 from Alcanivorax borkumensis SK2 and an Expression Vector for the Genes fadD from Escherichia coli and Wax-dgaT from Acinetobacter sp. ADP1 or atfA1 from Alcanivorax borkumensis

To create E. coli strains with expression vectors for the genes synUcTE from Umbellularia californica and ald from Bacillus subtilis and Cv_(—)2025 from Chromobacterium violaceum in combination with an expression vector for the genes ABO_(—)0200, ABO_(—)0201 and ABO_(—)0203 from Alcanivorax borkumensis SK2 (SEQ ID No. 117), coding for a ferredoxin (ABO_(—)0200; SEQ ID No. 118), a CYP_(—)153 monooxygenase (ABO_(—)0201; SEQ ID No. 119) and a ferredoxin oxidoreductase (ABO_(—)0203; SEQ ID No. 120) and an expression vector for the genes fadD from Escherichia coli and wax-dgaT from Acinetobacter sp. ADP1 or atfA1 from Alcanivorax borkumensis SK2, electrocompetent cells of E. coli JW5020-1 Kan^(S) are produced. This takes place in a manner known to those skilled in the art.

JW5020-1 Kan^(S) is sequentially transformed with the plasmids

-   1. pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE] (SEQ ID No. 38), -   2. pCDF[wax-dgaT_AsADP1(co_Ec)-fadD_Ec] (SEQ ID No. 16) bzw.     pCDF[atfA1_Ab(co_Ec)-fadD_Ec] (SEQ ID No. 17) -   3. pCOM10-AbCYP_(—)153 (SEQ ID No. 121)     and plated out onto LB agar plates containing kanamycin (50 μg/ml),     ampicillin (100 μg/ml) and spectinomycin (100 μg/ml). Transformants     are checked for the presence of the correct plasmids by plasmid     preparation and analytical restriction analysis.

The plasmid pCOM10-AbCYP_(—)153 (SEQ ID No. 121) is created starting from the plasmid pCOM10 (SEQ ID No. 97; Smits T H, Seeger M A, Witholt B, van Beilen J B. New alkane-responsive expression vectors for Escherichia coli and Pseudomonas. Plasmid. 2001. 46(1):16-24.). For this, pCOM10 is cleaved with EcoRI/SalI and the fragment containing the genes ABO_(—)0200, ABO_(—)0201 and ABO_(—)0203 from Alcanivorax borkumensis SK2 inserted.

This fragment is created by gene synthesis, wherein the sections from Alcanivorax borkumensis SK2 coding for the ferredoxin (ABO_(—)0200; SEQ ID No. 106), the CYP_(—)153 monooxygenase ABO_(—)0201; SEQ ID No. 107) and the ferredoxin oxidoreductase (ABO_(—)0203; SEQ ID No. 108) are not codon-optimized for translation in E. coli, but instead the wild type sequence is used.

In this manner, the following strains are constructed:

-   -   E. coli JW5020-1 Kan^(S)         pCOM10-AbCYP_(—)153/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE]/pCDF[wax-dgaT_AsADP1(co_Ec)-fadD_Ec]     -   E. coli JW5020-1 Kan^(S)         pCOM10-AbCYP_(—)153/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE]/pCDF[atfA1_Ab(co_Ec)-fadD_Ec]

These strains are subjected to a fed-batch fermentation in order to analyse their capacity for production of hydroxy fatty acid methyl esters, oxo fatty acid methyl esters, carboxy fatty acid methyl esters and amino fatty acid methyl esters from glucose. This is performed with an 8-fold parallel fermentation system from DASGIP, as described in Example 8.

It is shown that, with addition of 1% (v/v) methanol, these strains are capable of forming methyl laurate, methyl hydroxylaurate, methyl oxolaurate, methyl carboxylaurate and methyl aminolaurate and methyl tetradecanoate, methyl hydroxytetradecanoate, methyl oxotetradecanoate, methyl carboxytetradecanoate and methyl aminotetradecanoate from glucose.

Example 24 Production of Aminolauric Acid and Aminotetradecanoic Acid by E. coli Strains with Deletion of the Gene fadE and Expression Vectors for the Genes synUcTE from Umbellularia californica, and ald from Bacillus subtilis, and Cv_(—)2025 from Chromobacterium violaceum in Combination with an Expression Vector for the Genes ABO_(—)0200, ABO_(—)0201 and ABO_(—)0203 from Alcanivorax borkumensis SK2

To create E. coli strains with expression vectors for the genes synUcTE from Umbellularia californica and ald from Bacillus subtilis and Cv_(—)2025 from Chromobacterium violaceum in combination with an expression vector for the genes ABO_(—)0200, ABO_(—)0201 and ABO_(—)0203 from Alcanivorax borkumensis SK2 (SEQ ID No. 117), coding for a ferredoxin (ABO_(—)0200; SEQ ID No. 118), a CYP_(—)153 monooxygenase (ABO_(—)0201; SEQ ID No. 119) and a ferredoxin oxidoreductase (ABO_(—)0203; SEQ ID No. 120), electrocompetent cells of E. coli JW5020-1 Kan^(S) are produced. This takes place in a manner known to those skilled in the art.

JW5020-1 Kan^(S) is sequentially transformed with the plasmids

-   1. pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE] (SEQ ID No. 38) and -   2. pCOM10-AbCYP_(—)153 (SEQ ID No. 121) and plated out onto LB agar     plates containing kanamycin (50 μg/ml) and ampicillin (100 μg/ml).     Transformants are checked for the presence of the correct plasmids     by plasmid preparation and analytical restriction analysis.

In this manner, the following strain is constructed:

-   -   E. coli JW5020-1 Kan^(S)         pCOM10-AbCYP_(—)153/pJ294[alaDH_B.s._TA_C.v.(Ct)_Ptac-synUcTE]

This strain is subjected to a fed-batch fermentation in order to analyse its capacity for the production of hydroxy fatty acids, oxo fatty acids, carboxy fatty acids and amino fatty acids from glucose. This is performed with an 8-fold parallel fermentation system from DASGIP, as described in Example 8.

It is shown that this strain is capable of forming lauric acid, hydroxylauric acid, oxolauric acid, carboxylauric acid and aminolauric acid and tetradecanoic acid, hydroxytetradecanoic acid, oxotetradecanoic acid, carboxytetradecanoic acid and aminotetradecanoic acid from glucose. 

1. A microorganism comprising: a first genetic engineering modification, so that compared to its wild type it is capable of forming more carboxylic acid or carboxylate ester from at least one simple carbon source, and a second genetic engineering modification, such that the microorganism in comparison to its wild type displays increased activity of at least one enzyme E₁ that catalyzes the conversion of a carboxylic acid or a carboxylate ester to a corresponding ω-hydroxycarboxylic acid or ω-hydroxy-carboxylate ester.
 2. The microorganism of claim 1, wherein the enzyme E₁ is an E_(1a) P450 alkane hydroxylase or an E_(1b) AlkB alkane hydroxylase of EC 1.14.15.3.
 3. The microorganism of claim 1, wherein the second genetic modification is such that the microorganism in comparison to its wild type displays increased activity of at least one enzyme selected from the group consisting of: an enzyme E₂ that catalyzes the conversion of an ω-oxocarboxylic acid or an ω-oxocarboxylate ester to the corresponding ω-aminocarboxylic acid or ω-aminocarboxylate ester, an enzyme E₃ that catalyzes the conversion of an α-ketocarboxylic acid to an amino acid, an enzyme E₄ that catalyzes the conversion of an ω-hydroxycarboxylic or an ω-hydroxycarboxylate ester to the corresponding ω-oxocarboxylic acid or ω-oxocarboxylate ester, and an enzyme E₅ that catalyzes the conversion of an ω-oxocarboxylic acid or an ω-oxocarboxylate ester to the corresponding ω-carboxycarboxylic acid or ω-carboxycarboxylate ester.
 4. The microorganism of claim 3, wherein the second genetic modification comprises a combination of increased activities of the enzymes selected from the group consisting of E₁E₂E₃, E₁E₂E₃E₄, E₁E₅ and E₁E₄E₅.
 5. The microorganism of claim 3, wherein: the enzyme E₂ is an ω-transaminase, the enzyme E₃ is an alanine dehydrogenase of EC 1.4.1.1, the enzyme E₄ is a fatty alcohol oxidase of EC 1.1.3.20, an AlkJ alcohol dehydrogenase of EC 1.1.99.- or an alcohol dehydrogenase of EC 1.1.1.1 or EC 1.1.1.2, and the enzyme E₅ is an aldehyde dehydrogenase of EC 1.2.1.3, EC 1.2.1.4 or EC 1.2.1.5.
 6. The microorganism of claim 1, wherein the enzyme E₁ is an alkane monooxygenase from Pseudomonas putida GPo1 encoded by alkBGT or a protein having a polypeptide sequence wherein up to 60% of the amino acid residues compared to the alkane monooxygenase sequence are modified by deletion, insertion, substitution or a combination thereof and which still possesses at least 50% of the activity of the alkane monooxygenase.
 7. The microorganism of claim 1, wherein the second genetic modification is such that compared to its wild type the microorganism forms more alkL gene product.
 8. The microorganism of claim 7, wherein the alkL gene product is encoded by an alkL gene of gram-negative bacteria.
 9. The microorganism of claim 7, wherein the alkL gene product is selected from the group consisting of: a protein encoded by SEQ ID NO:1, a protein encoded by SEQ ID NO:3, a protein comprising a polypeptide sequence selected from the group consisting of SEQ ID NOs: 2, 4, 5, 6 and 7, and a protein having a polypeptide sequence wherein up to 60% of the amino acid residues compared to SEQ ID NO: 2, 4, 5, 6 or 7 are modified by deletion, insertion, substitution or a combination thereof and which still possesses at least 50% of the activity of the protein with the respective reference sequence SEQ ID NO: 2, 4, 5, 6 or
 7. 10. The microorganism of claim 1, which is a species selected from the group consisting of: E. coli, Pseudomonas sp., Pseudomonas fluorescens, Pseudomonas putida, Pseudomonas stutzeri, Acinetobacter sp., Burkholderia sp., Burkholderia thailandensis, Cyanobakterien, Klebsiella sp., Klebsiella oxytoca, Salmonella sp., Rhizobium sp. and Rhizobium meliloti, Bacillus sp., Bacillus subtilis, Clostridium sp., Corynebacterium sp., Corynebacterium glutamicum, Brevibacterium sp., Chlorella sp. and Nostoc sp.
 11. The microorganism of claim 1, wherein the first genetic modification is, compared to the enzymatic activity of the wild type of the microorganism, increased activity of at least one of the enzymes selected from the group consisting of: E₁ Acyl-ACP thioesterase, E_(ii) Acyl-CoA thioesterase, E_(iib) Acyl-CoA:ACP transacylase, E_(iii) Polyketide synthase, which catalyses a reaction which is involved in the synthesis of a carboxylic acid or a carboxylate ester, and E_(iv) Hexanoic acid synthase.
 12. The microorganism of claim 1, further comprising a third genetic modification which comprises, compared with the enzymatic activity of the wild type of the microorganism, increased activity of at least one of the enzymes E_(iib), E_(v), E_(vi), or E_(vii) which is involved in the conversion of carboxylic acids or ω-functionalized carboxylic acids to carboxylate esters or ω-functionalized carboxylate esters, selected from the group consisting of: E_(iib) Acyl-CoA:ACP transacylase, which converts an ACP thioester into a CoA thioester or a CoA thioester into an ACP thioester, E_(v) Wax ester synthase or alcohol O-acyltransferase, which catalyses the synthesis of an ester from an acyl-coenzyme A thioester or an acyl-ACP thioester and an alcohol, E_(vi) Acyl-CoA (coenzyme A) synthetase, which catalyses the synthesis of an acyl-coenzyme A thioester, and E_(vii) Acyl thioesterase, which catalyses the conversion of an acyl thioester with an alcohol to a carboxylate ester.
 13. The microorganism of claim 12, wherein the third genetic modification comprises a combination of increased activities of the enzymes selected from the group consisting of E_(v), E_(vii), E_(v)E_(vi), E_(vi)E_(vii) and E_(vi), E_(vii)E_(iib).
 14. The microorganism of claim 1, further comprising a fourth genetic modification which comprises, compared with the enzymatic activity of the wild type of the microorganism, increased activity of at least one of the enzymes selected from the group consisting of: E_(iib) Acyl-CoA (coenzyme A):ACP (acyl carrier protein) transacylase, which converts an ACP thioester into a CoA thioester or a CoA thioester into an ACP thioester, E_(vi) Acyl-CoA (coenzyme A) synthetase, which preferably catalyses the synthesis of an acyl-coenzyme A thioester, E_(viii) Acyl-CoA (coenzyme A) reductase, which preferentially catalyses the reduction of an acyl-coenzyme A thioester to the corresponding alkan-1-al or alkan-1-ol E_(ix) Fatty acid reductase, also fatty aldehyde dehydrogenase or arylaldehyde oxidoreductase, which preferentially catalyses the reduction of an alkanoic acid to the corresponding alkan-1-al, and E_(x) Acyl-ACP (acyl carrier protein) reductase, which preferentially catalyses the reduction of an acyl-ACP thioester to the corresponding alkan-1-al or alkan-1-ol.
 15. The microorganism of claim 14, wherein the second genetic modification comprises a combination of increased activities of the enzymes selected from the group consisting of E_(viii), E_(ix), E_(x), E_(vi)E_(viii), and E_(vi)E_(x)E_(iib).
 16. The microorganism of claim 1, further comprising a fifth genetic modification which comprises, compared with the enzymatic activity of the wild type of the microorganism, decreased activity of at least one of the enzymes selected from the group consisting of: E_(a) Acyl-CoA synthetase, which catalyses the synthesis of an acyl-coenzyme A thioester, E_(b) Acyl-CoA dehydrogenase, which catalyses the oxidation of an acyl-coenzyme A thioester to the corresponding enoyl-coenzyme A thioester, E_(c) Acyl-CoA-oxidase, which catalyses the oxidation of an acyl-coenzyme A thioester to the corresponding enoyl-coenzyme A thioester, E_(d) Enoyl-CoA hydratase, which catalyses the hydration of an enoyl-coenzyme A thioester to the corresponding 3-hydroxyacyl-coenzyme A thioester, E_(e) 3-hydroxyacyl-CoA dehydrogenase, which catalyses the oxidation of a 3-hydroxyacyl-coenzyme A thioester to the corresponding 3-oxoacyl-coenzyme A thioester and E_(f) Acetyl-CoA acyltransferase, which catalyses the transfer of an acyl residue from a 3-oxoacyl-coenzyme A thioester to Coenzyme A and thereby creates an acyl-coenzyme A thioester shortened by two carbon atoms.
 17. (canceled)
 18. A process for producing an ω-functionalized carboxylic acid or an ω-functionalized carboxylate ester from a simple carbon source, the process comprising: I) contacting the microorganism of claim 1 with a medium comprising a simple carbon source, II) culturing the microorganism under conditions that enable the microorganism to form the ω-functionalized carboxylic acid or ω-functionalized carboxylate ester from the simple carbon source and III) optionally isolating the ω-functionalized carboxylic acid or ω-functionalized carboxylate ester formed.
 19. The process of claim 18, wherein the ω-functionalized carboxylic acid is an ω-aminocarboxylic acid, or wherein the ω-functionalized carboxylate ester is an ω-aminocarboxylate ester.
 20. A process for producing a polyamide based on an ω-aminocarboxylic acid, the process comprising: (a1) producing an ω-aminocarboxylic acid by the process of claim, and (a2) polymerizing the ω-aminocarboxylic acid produced in (a1), optionally with an ω-aminocarboxylic not produced in (a1), to obtain a polyamide.
 21. A polyamide obtained by the process of claim
 20. 22. The process of claim 18, wherein the ω-functionalized carboxylic acid is an ω-hydroxycarboxylic acid, or wherein the ω-functionalized carboxylate ester is an ω-hydroxycarboxylate ester.
 23. The process of claim 18, wherein the ω-functionalized carboxylic acid is an ω-carboxycarboxylic acid, or wherein the ω-functionalized carboxylate ester is an ω-carboxycarboxylate ester. 